Cuprolinic Blue: a specific dye for single-stranded RNA in the presence of magnesium chloride. I. Fundamental aspects

Summary Qualitative and quantitative aspects of the cationic dye Cuprolinic Blue were investigated with model films of polyacrylamide gel in which RNA, DNA and other biological polyanionic compounds had been incorporated. In the presence of 1m MgCl₂, Curpolinic Blue was found to bind specifically to single-stranded RNA, leaving native DNA, proteins, (acid) polysaccharides and phospholipids completely unstained. Under these conditions, Cuprolinic Blue is complexed by non-electrostatic bonds with non-stacked purine bases, mainly adenine. Optimal conditions for dye binding and differentiation have been defined. Both the Cuprolinic Blue-MgCl₂ staining of single-stranded RNA and the Cuprolinic Blue staining of RNA and DNA in the absence of MgCl₂ were found to obey the Lambert-Beer law. The advantages and possible applications of Cuprolinic Blue are compared with well-known (indirect) histochemical RNA staining procedures.     

Characterization and classification of virus particles associated with hepatitis A. II. Type and configuration of nucleic acid.

Virus particles banding at 1.34 g/ml in CsCl and sedimenting at 160S in sucrose gradients were isolated from fecal specimens of patients suffering from hepatitis. In the presence of 4 M urea and about 90% formamide, these particles released linear nucleic acid molecules of the kinked appearance characteristic of single-stranded RNA or single-stranded DNA. They could be distinguished from the nucleic acid of phage lambda added to the preparation as a marker for double-stranded configuration. Experiments in which the virus particles under investigation were incubated at pH 12.9 at 50 degrees C for 30 min revealed that their nucleic acid molecules were hydrolyzed as readily as the RNA genome of poliovirus type 2 analyzed in parallel. Both the single-stranded DNA of phage phiX174 and that of parvovirus LuIII, however, proved unaffected by this treatment, and the double-stranded DNA of phage lambda was denatured to single-stranded molecules. It was concluded, therefore, that the virus of human hepatitis A contains a linear genome of single-stranded RNA and has to be classified with the picornaviruses.     

Determination of covalent binding to intact DNA, RNA, and oligonucleotides by intercalating anticancer drugs using high-performance liquid chromatography. Studies with doxorubicin and NADPH cytochrome P-450 reductase.

An HPLC method is described which can determine covalent binding to intact nucleic acid by intercalating anticancer drugs and at the same time remove noncovalently bound intercalated drug. The method uses a column containing a nonporous 2-microns DEAE anion-exchange resin capable of chromatographing nucleic acids greater than 50,000 bases in size in under 1 h. After priming with 1 mg of DNA, the column behaves as an intercalator affinity column, strongly retaining the drug while allowing the nucleic acid to pass through normally. Retained drug is released with an injection of 0.1 M potassium hydroxide. Incubations were performed with the intercalator doxorubicin, which is also believed to bind covalently to DNA. When [14C]doxorubicin was mixed with DNA, at a concentration where all the drug would bind by intercalation, the column retained 82% of the total radioactivity, only 18% migrated with the nucleic acid. If the DNA was mildly denatured by treatment with 2 M sodium chloride at 50 degrees C for 45 min before chromatography, then 99.8% of total radioactivity was retained, only background counts migrated with the nucleic acid, as was the case with single-stranded DNA and RNA without any treatment. Purified NADPH cytochrome P-450 reductase was used to activate doxorubicin. DNA inhibited the metabolism of the drug by the enzyme, no covalent binding occurred with RNA, low levels occurred with single-stranded DNA (34 pmol/100 micrograms), and the highest levels were recorded with oligonucleotides (243 pmol/100 micrograms). The assay was sufficiently sensitive to measure covalent binding to DNA extracted from MCF-7 human breast cancer cells treated with 50 microM [14C]doxorubicin (18.6 pmol/100 micrograms). Thus, covalent binding to DNA, RNA, and oligonucleotides by intercalators can be measured quickly (20 min) without the need to either digest the nucleic acid or subject it to long sample preparation techniques.     

Characterization of SYBR Gold nucleic acid gel stain: a dye optimized for use with 300-nm ultraviolet transilluminators

The highest sensitivity nucleic acid gel stains developed to date are optimally excited using short-wavelength ultraviolet or visible light. This is a disadvantage for laboratories equipped only with 306- or 312-nm UV transilluminators. We have developed a new unsymmetrical cyanine dye that overcomes this problem. This new dye, SYBR Gold nucleic acid gel stain, has two fluorescence excitation maxima when bound to DNA, one centered at approximately 300 nm and one at approximately 495 nm. We found that when used with 300-nm transillumination and Polaroid black-and-white photography, SYBR Gold stain is more sensitive than ethidium bromide, SYBR Green I stain, and SYBR Green II stain for detecting double-stranded DNA, single-stranded DNA, and RNA. SYBR Gold stain's superior sensitivity is due to the high fluorescence quantum yield of the dye-nucleic acid complexes ( approximately 0.7), the dye's large fluorescence enhancement upon binding to nucleic acids ( approximately 1000-fold), and its capacity to more fully penetrate gels than do the SYBR Green gel stains. We found that SYBR Gold stain is as sensitive as silver staining for detecting DNA-with a single-step staining procedure. Finally, we found that staining nucleic acids with SYBR Gold stain does not interfere with subsequent molecular biology protocols.     

In vitro preparation of amelogenin nanoparticles carrying nucleic acids

Amelogenin, a matrix protein involved in biomineralization of enamel, can self-assemble to form nanospheres in a pH-dependent manner. Nucleic acids (single-stranded, double-stranded, and plasmid DNA, as well as RNA) could be co-precipitated with amelogenin, demonstrating a strong binding of nucleic acids to amelogenin. The amounts of co-precipitated nucleic acids were analyzed and binding levels upto 90 μg DNA/mg amelogenin was achieved. The co-precipitation could also be carried out in a bacterial cell homogenate, and no bacterial proteins were found in the amelogenin aggregates, suggesting specificity for nucleic acid binding. Dynamic light scattering showed that amelogenin nanosphere structure is maintained upon DNA binding with an upto 2.6 nm increase in diameter. The reported binding of nucleic acids to amelogenin can be explored practically for nucleic acid separation.     

Differences in the red fluorescence of acridine orange bound to single-stranded RNA and DNA.

Fluorescence of acridine orange bound to RNA or DNA in the single-stranded form including single-stranded synthetic polyribo- or polydeoxyribonucleotides was measured in the expectation that some distinct structural characteristic between single-stranded RNA and DNA might be reflected by a specific fluorescent behaviour of bound dyes. It was found that the complex of the dye with single-stranded RNA emits a weaker red fluorescence around 650 nm than the complex with single-stranded DNA at low phosphate-to-dye ratios. The fact could be explained neither by a direct interaction of bound dyes with the 2′-hydroxyl group of ribose in RNA nor by the difference in the G-C content of the nucleic acids. On the basis of the character of dye molecules emitting the red fluorescence, it was suggested that the bases in single-stranded RNA might be buried in some hydrophobic environment that would make the dyes less likely to interact with them, compared with the bases in single-stranded DNA. It was further inferred that some conformational rigidity of single-stranded RNA may partially be responsible for the weaker red fluorescence.     

Staining of proteoglycans in mouse lung alveoli. I. Ultrastructural localization of anionic sites

Summary In order to contrast anionic sites, in mouse lung alveoli, two staining procedures were applied: (a) staining with Ruthenium Red and Alcian Blue and (b) staining with Cuprolinic Blue in a critical electrolyte concentration method. The Ruthenium Red-Alcian Blue staining procedure revealed electron-dense granules in the alveolar basement membrane. The granules were closely associated with the epithelial cell membrane and continued to stain even when the procedure was carried out at a low pH, indicating the presence of sulphate groups in the granules.After staining with Cuprolinic Blue, electron-dense filaments, also closely associated with the cell membrane, became visible in the basement membrane of type I epithelial cells. Their length depended on the MgCl₂ concentration used during staining. At 0.4m MgCl₂, the length was mostly within the range 100–180 nm. Using a modified Cuprolinic Blue method, the appearance of the filaments closely resembled that of spread proteoglycan monomers with their side-chains condensed. The basement membrane of type II epithelial cells also contained filaments positive towards Cuprolinic Blue; their length, however, was smaller in comparison with those of type I epithelial cells. The filaments lay in one plane and provided the whole alveolus with an almost continuous sheet of anionic sites. Cuprolinic Blue staining also revealed filaments in the basement membrane of the capillary endothelial cells. Furthermore, Cuprolinic Blue-positive filaments (average length about 40 nm) became apparent in close contact with collagen fibrils and separated from each other according to the main banding period of the collagen fibrils (about 60 nm), indicating a specific ultrastructural interaction between these two components. Filaments connecting collagen fibrils with each other were also detected.     

Nanopores and nucleic acids: prospects for ultrarapid sequencing

DNA and RNA molecules can be detected as they are driven through a nanopore by an applied electric field at rates ranging from several hundred microseconds to a few milliseconds per molecule. The nanopore can rapidly discriminate between pyrimidine and purine segments along a single-stranded nucleic acid molecule. Nanopore detection and characterization of single molecules represents a new method for directly reading information encoded in linear polymers. If single-nucleotide resolution can be achieved, it is possible that nucleic acid sequences can be determined at rates exceeding a thousand bases per second.     

Metachromatic staining and electron dense reaction of glycosaminoglycans by means of Cuprolinic Blue

Summary The cationic phthalocyanin-like dye Cuprolinic Blue, unlike phthalocyanin dyes such as Alcian Blue or Astra Blue, can definitely exhibit a clear metachromatic reaction with appropriate substrates, The application of Cuprolinic Blue to epoxy-embedded semithin sections revealed that mast cell cytoplasmic granules, goblet cell mucin and cartilage matrix stained in violet shades (metachromatic), whereas nuclear chromatin presented a bright blue coloration (orthochromatic). The metachromatic structures showed a high degree of contrast when ultrathin sections treated with Cuprolinic Blue were examined by electron microscopy.Cytophotometric measurements of stained components from the large intestine showed different absorption maxima: at 580 nm for mucin and at 640 nm for nuclei. The spectroscopical analysis revealed a clear-cut metachromatic shift when the dye was in the presence of chondroitin—4-sulphate. The addition of aluminium metal to Cuprolinic Blue solutions resulted in a striking spectral change; under such conditions the dye showed absorption maximum at 530 nm.     

Tight binding of a copper (II) phthalocyanine (cuprolinic blue) to DNA

The binding of a cationic phthalocyanine (Cuprolinic Blue) to calf thymus DNA, indicated by the increase in the DNA melting temperature and spectroscopic titration (Kaff greater than 10(7)M-1), was characterised by at least two distinct DNA-bound ligand forms possibly arising from intercalated and externally bound species each with Kaff values in the region 10(7) M-1. Evidence of strong intercalation was provided by gel electrophoresis of plasmid DNA in the presence of Cuprolinic Blue. The anionic phthalocyanine (copper phthalocyanine 3,4',4", 4"'-tetrasulfonic acid) does not bind to DNA by spectral criteria, reflecting electrostatic contributions to binding.     

A homogeneous nucleic acid hybridization assay based on strand displacement.

A homogeneous nucleic acid hybridization assay which is conducted in solution and requires no separation steps is described. The assay is based on the concept of strand displacement. In the strand displacement assay, an RNA "signal strand" is hybridized within a larger DNA strand termed the "probe strand", which is, in turn, complementary to the target nucleic acid of interest. Hybridization of the target nucleic acid with the probe strand ultimately results in displacement of the RNA signal strand. Strand displacement, therefore, causes conversion of the RNA from double to single-stranded form. The single-strand specificity of polynucleotide phosphorylase (EC 2.7.7.8) allows discrimination between double-helical and single-stranded forms of the RNA signal strand. As displacement proceeds, free RNA signal strands are preferentially phosphorolyzed to component nucleoside diphosphates, including adenosine diphosphate. The latter nucleotide is converted to ATP by pyruvate kinase(EC 2.7.1.40). Luciferase catalyzed bioluminescence is employed to measure the ATP generated as a result of strand displacement.     

Consequences of nucleic acid conformation on the binding of a trinuclear platinum drug.

BBR3464, a charged trinuclear platinum compound, is the first representative of a new class of anticancer drugs to enter phase I clinical trials. The structure of BBR3464 is characterized by two [trans-PtCl(NH(3))(2)] units linked by a tetraamine [trans-Pt(NH(3))(2)?H(2)N(CH(2))(6)NH(2)?(2)] unit. The +4 charge of BBR3464 and the separation of the platinating units indicate that the mode of DNA binding will be distinctly different from those of classical mononuclear drugs such as cisplatin, cis-[PtCl(2)(NH(3))(2)]. The reaction of BBR3464 with three different nucleic acid conformations was assessed by gel electrophoresis. Comparison of single-stranded DNA, RNA, and double-stranded DNA indicated that the reaction of BBR3464 with single-stranded DNA and RNA was faster than that with duplex DNA, and produced more drug-DNA and drug-RNA adducts. Electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry was used to further characterize the binding modes of BBR3464 with the DNA substrates. BBR3464 binding to different nucleic acid conformations raises the possibility that the adducts of single-stranded DNA and RNA may play a role in the different antitumor efficacies of this novel drug as compared with cisplatin.     

Specific detection of DNA and RNA targets using a novel isothermal nucleic acid amplification assay based on the formation of a three-way junction structure

The formation of DNA three-way junction (3WJ) structures has been utilised to develop a novel isothermal nucleic acid amplification assay (SMART) for the detection of specific DNA or RNA targets. The assay consists of two oligonucleotide probes that hybridise to a specific target sequence and, only then, to each other forming a 3WJ structure. One probe (template for the RNA signal) contains a non-functional single-stranded T7 RNA polymerase promoter sequence. This promoter sequence is made double-stranded (hence functional) by DNA polymerase, allowing T7 RNA polymerase to generate a target-dependent RNA signal which is measured by an enzyme-linked oligosorbent assay (ELOSA). The sequence of the RNA signal is always the same, regardless of the original target sequence. The SMART assay was successfully tested in model systems with several single-stranded synthetic targets, both DNA and RNA. The assay could also detect specific target sequences in both genomic DNA and total RNA from Escherichia coli. It was also possible to generate signal from E.coli samples without prior extraction of nucleic acid, showing that for some targets, sample purification may not be required. The assay is simple to perform and easily adaptable to different targets.     

The release of radioactive nucleic acids and mucoproteins by trypsin and ethylenediaminetetra-acetate treatment of baby-hamster cells in tissue culture

Monolayers of baby-hamster kidney cells were grown on glass in tissue culture and harvested with trypsin or EDTA in order to investigate the cell surface macromolecules removed by these cell-disaggregating agents. The release of nucleic acids from the cells during the harvesting procedure was monitored by labelling the cellular RNA with [5-(3)H]uridine and the cellular DNA with [2-(14)C]thymidine. Treatment of the cells with EDTA was found to cause an increase in the permeability of the plasma membrane with 7.6% of the cellular RNA, but less than 1% of the cellular DNA, being released. Moreover, 61% of the cells harvested with EDTA were permeable to Trypan Blue. With crude trypsin, lysis of the cell occurred with the release of similar amounts of RNA and DNA amounting to about 11% of the total cellular nucleic acid. In contrast, crystalline trypsin released only 1% of the cellular nucleic acids. Since virtually all the cells (99%) after harvesting in crystalline trypsin were impermeable to Trypan Blue, this method was suitable for obtaining cell surface macromolecules without contamination by intracellular damage. [1-(14)C]Glucosamine was incorporated by the cells only into bound hexosamines and sialic acids. [By monitoring the release of radioactivity in high-molecular-weight material in such experiments a measure of the release of macromolecules containing amino sugars was obtained.] Of the total macromolecules containing amino sugars in the cells 33%, 24% and 13% were released when the cells were harvested with crude trypsin, crystalline trypsin or EDTA respectively. Crystalline trypsin also released 39% of the total sialic acid of the cell, whereas less than 1% of the cellular sialic acid was present in the EDTA-treated fraction. It is concluded that the macromolecules containing amino sugars released with crude trypsin and EDTA are likely to be heavily contaminated with intracellular material. However, the macromolecules released by crystalline trypsin appear to come from the cell surface.     

The geminivirus BR1 movement protein binds single-stranded DNA and localizes to the cell nucleus.

Plant viruses encode movement proteins that are essential for infection of the host but are not required for viral replication or encapsidation. Squash leaf curl virus (SqLCV), a bipartite geminivirus with a single-stranded DNA genome, encodes two movement proteins, BR1 and BL1, that have been implicated in separate functions in viral movement. To further elucidate these functions, we have investigated the nucleic acid binding properties and cellular localization of BR1 and BL1. In this study, we showed that BR1 binds strongly to single-stranded nucleic acids, with a higher affinity for single-stranded DNA than RNA, and is localized to the nucleus of SqLCV-infected plant cells. In contrast, BL1 binds only weakly to single-stranded nucleic acids and not at all to double-stranded DNA. The nuclear localization of BR1 and the previously demonstrated plasma membrane localization of BL1 were also observed when these proteins were expressed from baculovirus vectors in Spodoptera frugiperda insect cells. The biochemical properties and cellular locations of BR1 and BL1 suggest a model for SqLCV movement whereby BR1 is involved in the shuttling of the genome in and/or out of the nucleus and BL1 acts at the plasma membrane/cell wall to facilitate viral movement across cell boundaries.     

Phage formation in Staphylococcus muscae cultures; nucleic acid synthesis during virus formation

1. The total nucleic acid synthesized by normal and by infected S. muscae suspensions is approximately the same. This is true for either lag phase cells or log phase cells. 2. The amount of nucleic acid synthesized per cell in normal cultures increases during the lag period and remains fairly constant during log growth. 3. The amount of nucleic acid synthesized per cell by infected cells increases during the whole course of the infection. 4. Infected cells synthesize less RNA and more DNA than normal cells. The ratio of RNA/DNA is larger in lag phase cells than in log phase cells. 5. Normal cells release neither ribonucleic acid nor desoxyribonucleic acid into the medium. 6. Infected cells release both ribonucleic acid and desoxyribonucleic acid into the medium. The time and extent of release depend upon the physiological state of the cells. 7. Infected lag phase cells may or may not show an increased RNA content. They release RNA, but not DNA, into the medium well before observable cellular lysis and before any virus is liberated. At virus liberation, the cell RNA content falls to a value below that initially present, while DNA, which increased during infection falls to approximately the original value. 8. Infected log cells show a continuous loss of cell RNA and a loss of DNA a short time after infection. At the time of virus liberation the cell RNA value is well below that initially present and the cells begin to lyse.     

Theoretical studies on protein-nucleic acid interactions. I. Interaction of positively charged amino acids with nucleic acid fragments

Coulombic interactions between the side chains of charged amino acids (Arg⁺, Lys⁺, and His⁺) and negatively charged phosphate groups of nucleic acid fragments have been studied theoretically. Diribose monophosphate and dideoxyribose monophosphate are chosen as model systems for single-stranded RNA and DNA, respectively. The interaction energies have been calculated by second-order perturbation theory using simplified formulas for individual terms. The interaction energy in this formalism is a sum of electrostatic, polarization, dispersion, and repulsive energies. Our results show that about 90% of the total interaction energy is contributed by the electrostatic term alone. Contribution from the repulsive term exceeds that from the dispersion term. Calculated interaction energies suggest that Lys⁺ and His⁺ form more stable complexes with RNA than with single-stranded DNA. On the other hand, Arg⁺ has a higher affinity for DNA than for RNA. The affinity of nucleic acids for the three amino acids is in the order Lys⁺ > His⁺ > Arg⁺. Further, the basic amino acid residues form more stable complexes with A-DNA than with B-DNA. The role of the Coulombic interactions in the specific recognition of nucleic acids by proteins is discussed.     

Purification and characterization of the Upf1 protein: a factor involved in translation and mRNA degradation.

mRNA degradation is an important control point in the regulation of gene expression and has been shown to be linked to the process of translation. One clear example of this linkage is the observation that nonsense mutations in a gene can accelerate the decay of the corresponding mRNA. In the yeast Saccharomyces cerevisiae, the product of the UPF1 gene, harboring zinc finger, NTP hydrolysis, and helicase motifs, was shown to be a trans-acting factor in this decay pathway. A UPF1 gene disruption results in stabilization of nonsense-containing mRNAs and leads to a nonsense suppression phenotype. As a first step toward understanding the molecular and biochemical mechanism of nonsense-mediated mRNA decay, we have purified Upf1p from a yeast extract and characterized its nucleic acid-dependent NTPase activity, helicase activity, and nucleic acid binding properties. The results presented in this paper demonstrate that Upf1p contains both RNA- and DNA-dependent ATPase activities and RNA and DNA helicase activities. In the absence of ATP, Upf1p binds to single-stranded RNA or DNA, whereas hydrolysis of ATP facilitates its release from single-stranded nucleic acid. Based on these results, the role of Upf1p's biochemical activities in mRNA decay and translation are discussed.     

Comparison of DNA and RNA quantification methods suitable for parameter estimation in metabolic modeling of microorganisms

Recent developments in cellular and molecular biology require the accurate quantification of DNA and RNA in large numbers of samples at a sensitivity that enables determination on small quantities. In this study, five current methods for nucleic acid quantification were compared: (i) UV absorbance spectroscopy at 260 nm, (ii) colorimetric reaction with orcinol reagent, (iii) colorimetric reaction based on diphenylamine, (iv) fluorescence detection with Hoechst 33258 reagent, and (v) fluorescence detection with thiazole orange reagent. Genomic DNA of three different microbial species (with widely different G+C content) was used, as were two different types of yeast RNA and a mixture of equal quantities of DNA and RNA. We can conclude that for nucleic acid quantification, a standard curve with DNA of the microbial strain under study is the best reference. Fluorescence detection with Hoechst 33258 reagent is a sensitive and precise method for DNA quantification if the G+C content is less than 50%. In addition, this method allows quantification of very low levels of DNA (nanogram scale). Moreover, the samples can be crude cell extracts. Also, UV absorbance at 260 nm and fluorescence detection with thiazole orange reagent are sensitive methods for nucleic acid detection, but only if purified nucleic acids need to be measured.