STUDIES ON NUCLEIC ACID METACHROMASY : II. Metachromatic and Orthochromatic Staining by Toluidine Blue of Nucleic Acids in Tissue Sections

Acrolein-fixed, polyester wax-embedded tissue sections showed excellent preservation of light microscopic architecture and, when stained with toluidine blue, intense color contrast between DNA, which stained orthochromatically, and RNA, which stained metachromatically. This method has practical value for differentiating DNA from RNA in the same section. The color contrast was impaired by substituting formaldehyde for acrolein or paraffin for polyester wax, and was negligible in tissues fixed in formaldehyde or Carnoy's fluid and embedded in paraffin. Quality of structural preservation paralleled degree of color contrast. Metachromatic staining can be analysed, by the quantitative parameters of Bradley and colleagues, to provide inferences regarding the conformation of biopolymers in tissue sections. Comparison of the nucleic acid color contrasts in toluidine blue-stained sections with titrations of fixative-treated nucleic acids against toluidine blue in solution indicated a greater difference in conformation between DNA- and RNA-protein in acrolein-polyester sections than between acrolein-treated free DNA and RNA in solution. This is supported by recent evidence that the conformation of ribosomal RNA is quite different in whole ribosomes from that assumed by the same RNA free in solution. The acrolein-polyester method may enhance color contrast by providing superior preservation of ordered nucleoprotein conformations.     

Highly Selective Acridine and Ethidium Staining of Bacterial DNA and RNA

The acridine dyes acridine orange (AO) and coriphosphine O (CPO) and ethidium bromide (EtBr) were used to stain bacterial digests after electrophoresis in native and denaturing (SDS) polyacrylamide gels and were shown to stain DNA and RNA preferentially over other subcellular components in the gels. Vegetative cell digests of Bacillus subtilis, Escherichia coli, Micrococcus luteus, and Staphylococcus aureus showed intense staining of DNA with AO and CPO near the top of the gel, but little or no staining of other cellular constituents. EtBr stained both DNA and RNA in the gels. Protein standards and non-nucleic acid cellular constituents stained faintly with high concentrations (> 100 μM) of AO, lower concentrations (13.9 μM) of CPO, and did not stain with 0.5 μg/ml EtBr in denaturing gels. The complete set of cellular biochemicals was visualized by silver staining, while the protein subset was detected by Coomassie blue staining. The highest concentrations of AO (120 μM) and CPO (13.9 μM) were shown to detect purified DNA in gels with a sensitivity in the range of 25–50 ng per band. This work demonstrates the specificity of acridine and ethidium dyes for nucleic acids, while illustrating the level of non-nucleic acid-specific interactions with other cellular components by staining of electrophoretically separated cellular components in a gel matrix.     

Effect of fixation in Carnoy's solution on nucleic acid and protein concentration in the rabbit superior cervical sympathetic ganglion]

By means of biochemical techniques, the stability of RNA, DNA and protein contents has been demonstrated in the rabbit superior cervical sympathetic node fixed in Carnoy's solution for 2 hours at 4 degrees C. A 2 hour fixation in Carnoy's fluid at room temperature, results, however, in a considerable loss of RNA (21%). The loss of DNA and protein did not exceed 2% of the total amount of the fresh ganglion tissue. Fixation at a higher temperature (37%) increased the loss percentage protein and of nucleic acids: 3.1, 5.5 and 42%, for protein, DNA and RNA, resp.     

Denaturation of nucleic acids induced by intercalating agents. Biochemical and biophysical properties of acridine orange-DNA complexes

At high binding densities acridine orange (AO) forms complexes with ds DNA which are insoluble in aqueous media. These complexes are characterized by high red- and minimal green-luminescence, 1:1 (dye/P) stoichiometry and resemble complexes of AO with ss nucleic acids. Formation of these complexes can be conveniently monitored by light scatter measurements. Light scattering properties of these complexes are believed to result from the condensation of nucleic acids induced by the cationic, intercalating ligands. The spectral and thermodynamic data provide evidence that AO (and other intercalating agents) induces denaturation of ds nucleic acids; the driving force of the denaturation is high affinity and cooperativity of binding of these ligands to ss nucleic acids. The denaturing effects of AO, adriamycin and ellipticine were confirmed by biochemical studies on accessibility of DNA bases (in complexes with these ligands) to the external probes. The denaturing properties of AO vary depending on the primary structure (sugar- and base-composition) of nucleic acids.     

A Differential Stain for Nucleic Acids

An easily used trichrome stain consisting of orange G, methyl green, and toluidine blue is proposed as a method of differentiating desoxyribonucleic acid (DNA) and ribonucleic acid (RNA) in cells. Carnoy's acetic-alcohol is the fixative of choice, though cold acetone is also satisfactory. Photomicrographs taken with ultraviolet and visible light show that the structures containing nucleic acid are exactly those which stain with methyl green and toluidine blue. Studies with nucleases and extraction of nucleic acids with cold and hot perchloric acid further indicate a specificityy of the dyes for DNA and RNA. Present experiments are directed toward using the stain for quantitative estimation of the nucleic acids.     

In silico single strand melting curve: a new approach to identify nucleic acid polymorphisms in Totiviridae

Background

The PCR technique and its variations have been increasingly used in the clinical laboratory and recent advances in this field generated new higher resolution techniques based on nucleic acid denaturation dynamics. The principle of these new molecular tools is based on the comparison of melting profiles, after denaturation of a DNA double strand. Until now, the secondary structure of single-stranded nucleic acids has not been exploited to develop identification systems based on PCR. To test the potential of single-strand RNA denaturation as a new alternative to detect specific nucleic acid variations, sequences from viruses of the Totiviridae family were compared using a new in silico melting curve approach. This family comprises double-stranded RNA virus, with a genome constituted by two ORFs, ORF1 and ORF2, which encodes the capsid/RNA binding proteins and an RNA-dependent RNA polymerase (RdRp), respectively.

Results

A phylogenetic tree based on RdRp amino acid sequences was constructed, and eight monophyletic groups were defined. Alignments of RdRp RNA sequences from each group were screened to identify RNA regions with conserved secondary structure. One region in the second half of ORF2 was identified and individually modeled using the RNAfold tool. Afterwards, each DNA or RNA sequence was denatured in silico using the softwares MELTSIM and RNAheat that generate melting curves considering the denaturation of a double stranded DNA and single stranded RNA, respectively. The same groups identified in the RdRp phylogenetic tree were retrieved by a clustering analysis of the melting curves data obtained from RNAheat. Moreover, the same approach was used to successfully discriminate different variants of Trichomonas vaginalis virus, which was not possible by the visual comparison of the double stranded melting curves generated by MELTSIM.

Conclusion

In silico analysis indicate that ssRNA melting curves are more informative than dsDNA melting curves. Furthermore, conserved RNA structures may be determined from analysis of individuals that are phylogenetically related, and these regions may be used to support the reconstitution of their phylogenetic groups. These findings are a robust basis for the development of in vitro systems to ssRNA melting curves detection.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2105-15-243) contains supplementary material, which is available to authorized users.     

Molecular Complexes of acridine orange and nucleosides

Summary The addition of various nucleosides to the aqueous AO solution brings about the red shift of the absorption band of AO monomer and the enhancement of the AO fluorescence emission. These phenomena are attributable to the formation of a kind of molecular complex between AO monomer and nucleoside.The absorption and fluorescence characteristics and their thermal behaviours enable us to determine the association constant and the binding energy. The binding energy of AO with purines is larger than that with pyrimidines, and the association constant between AO and the deoxyribonucleoside is larger than that between AO and the ribonucleoside. For the molecular complexes dealt with, the face-to-face arrangement of AO and nucleoside, linking of AO with sugar by hydrogen bridge, may be more preferential than the side-by-side arrangement with the direct linkage between AO and nucleic acid base by hydrogen bonding. The Van der Waals-London interactions may be one of the essential factors for the binding in these molecular complexes.The association constant and the binding energy for AO-DNA and -RNA systems were also determined. The magnitude of these quantities seems to reflect the difference in the structure of these nucleic acids. The rather open structure of RNA compared with DNA is in favour of affinity with AO and gives the larger association constant than that for AO-DNA. The binding energy is somewhat larger for AO-DNA complex than for AO-RNA complex, probably due to the structural difference of the base arrangement; the stacked base pairs for DNA and the stacked bases for RNA.This may explain the selective degradation [12] of guanine photo-sensitized by dyes either in the free state or when incorporated to DNA or RNA, as discussed elsewhere.     

Structural basis of nucleic acid binding by Nicotiana tabacum glycine-rich RNA-binding protein: implications for its RNA chaperone function

Glycine-rich RNA-binding proteins (GR-RBPs) are involved in cold shock response of plants as RNA chaperones facilitating mRNA transport, splicing and translation. GR-RBPs are bipartite proteins containing a RNA recognition motif (RRM) followed by a glycine-rich region. Here, we studied the structural basis of nucleic acid binding of full-length Nicotiana tabacum GR-RBP1. NMR studies of NtGR-RBP1 show that the glycine-rich domain, while intrinsically disordered, is responsible for mediating self-association by transient interactions with its RRM domain (NtRRM). Both NtGR-RBP1 and NtRRM bind specifically and with low micromolar affinity to RNA and single-stranded DNA. The solution structure of NtRRM shows that it is a canonical RRM domain. A HADDOCK model of the NtRRM–RNA complex, based on NMR chemical shift and NOE data, shows that nucleic acid binding results from a combination of stacking and electrostatic interactions with conserved RRM residues. Finally, DNA melting experiments demonstrate that NtGR-RBP1 is more efficient in melting CTG containing nucleic acids than isolated NtRRM. Together, our study supports the model that self-association of GR-RBPs by the glycine-rich region results in cooperative unfolding of non-native substrate structures, thereby enhancing its chaperone function.     

THERMAL DEPOLARIZATION OF FLUORESCENCE FROM POLYTENE CHROMOSOMES STAINED WITH ACRIDINE ORANGE

The degree of polarization of fluorescence from stretched Chironomus thummi polytene chromosomes, stained with low concentrations of acridine orange (AO), decreases with increasing temperature. The "half temperature" of this decrease (T_½R) is lower than the expected DNA thermal denaturation temperature (T_m) by about 20°C. T_½R is lowered as histone is removed from chromosomes. Balbiani ring regions of the fourth chromosome have T_½R's much lower than other regions, and nearly as low as chromosomes which had been extensively pretreated with trypsin to remove histone and other proteins. Measurements of the thermal change in the rotational diffusion rate of AO in solution with DNA indicate that the temperature at which the DNA-AO bonding changes from a "rigid" to a "loose" mode varies with the GC percentage of the DNA, and in the same fashion as T_m, although 20°C lower.     

Denaturation and condensation of intracellular nucleic acids monitored by fluorescence depolarization of intercalating dyes in individual cells

The intercalating binding of planar aromatic dye molecules to nucleic acids can be analyzed using fluorescence depolarization measurements of the dye molecules excited by linearly polarized light. In this study, we investigated the conformational changes of the intracellular DNA-dye complex in single cells. Flow cytometry, combined with a newly developed double-beam autocompensation technique, permitted rapid high-precision fluorescence depolarization measurements on a large number of individual cells. The dyes ethidium bromide (EB), propidium iodide (PI), and acridine orange (AO) were used in this study. Depending on the dye-to-phosphate ratio of the nuclear acid-dye complex, as well as on the spatial dye structure itself, internal and external binding sites can be monitored by fluorescence depolarization analysis. Both energy transfer and rotation and vibration of the dye molecules cause depolarization of the fluorescence emission. Differences in the concentration-dependent dye fluorescence depolarization values between PI and EB on one side and AO on the other side can be interpreted as a denaturation and condensation of double-stranded DNA regions by AO. We further show that the fluorescence polarization measurement technique can be used in an alternative way to monitor thermal denaturation of cellular DNA.     

Maize mitochondria: purification and characterization of ribosomes and ribosomal ribonucleic Acid

Mitochondria were prepared from etiolated maize shoots (Zea mays L. var. McNair 508) by homogenization followed by differential centrifugation and equilibrium banding in discontinuous sucrose or Renografin-sucrose gradients. Mitochondria prepared by sucrose banding showed better physiological integrity than those prepared by renografin-sucrose banding, although both procedures yielded mitochondria that showed respiratory control and coupling of oxidation to phosphorylation of ADP. Mitochondria prepared by Renografin-sucrose banding were free of dectectable cytoplasmic ribosomal RNA, while sucrose banding resulted in a low level of contamination. Ribosomes isolated from mitochondria sedimented at about 78S, with subunits sedimenting at 60 and 44S. Using Escherichia coli ribosomal RNA as internal standards, the molecular weights of mitochondrial ribosomal RNAs were found to be 0.74 to 0.75 and 1.26 × 10⁶ daltons by polyacrylamide gel electrophoresis, before or after denaturation in formaldehyde. Cytoplasmic ribosomal RNA molecular weights were 0.70 and 1.26 × 16⁶ before denaturation, and 0.68 and 1.5 × 10⁶ after denaturation, suggesting an unusual reaction of the heavy ribosomal RNA to formaldehyde.     

The correlation between uptake of Methyl Green and Feulgen staining intensity of cell nuclei. An image analysis study

Summary Paraffin sections of rat tissue fixed in either formaldehyde solution (3.6% w/v) or in Carnoy's fluid were stained using standardized Methyl Green—Pyronin procedures with the dyes used either simultaneously or in sequence. The sections were evaluated for the uptake of the two dyes by cell nuclei, nucleoli and cytoplasm using colour TV-image analysis. The parameters measured were integrated optical density and the surface area of the object. The sections were then destained and a Feulgen reaction was performed. The coordinates of the cells measured after the simultaneous Methyl Green—Pyronin method were stored in the computer, making it possible to measure the same cells in the Feulgen-restained sections. Image analysis gave results which invalidate the sequential methods as opposed to the simultaneous method. Mean optical densities were significantly increased for both dyes with the simultaneous method after formaldehyde fixation as compared to Carnoy fixation. The quantitative correlation of Methyl Green and DNA in the simultaneous technique was found to parallel exactly that of the Feulgen stain. In conclusion, the simultaneous Methyl Green—Pyronin technique is recommended while the sequential methods seem to be of less value.     

Physicochemical Studies on the Reaction between Formaldehyde and DNA

The reaction between formaldehyde and phage T7 DNA has been studied by optical absorbance and sedimentation measurements. Through the course of denaturation, OD₂₀₀ and s_{20, w} rise; after the attainment of full hyperchromicity the s_{20, w} falls sharply, suggesting a decrease in molecular weight. Conditions in which formaldehyde causes cross-linking are defined. Some experimental applications of the denaturation technique are given. Evidence which suggests that preformed single-strand interruptions may exist in phage DNA is briefly discussed.     

Sequence- and structural-selective nucleic acid binding revealed by the melting of mixtures

A simple method for the detection of sequence- and structural-selective ligand binding to nucleic acids is described. The method is based on the commonly used thermal denaturation method in which ligand binding is registered as an elevation in the nucleic acid melting temperature (T_m). The method can be extended to yield a new, higher -throughput, assay by the simple expediency of melting designed mixtures of polynucleotides (or oligonucleotides) with different sequences or structures of interest. Upon addition of ligand to such mixtures at low molar ratios, the T_m is shifted only for the nucleic acid containing the preferred sequence or structure. Proof of principle of the assay is provided using first a mixture of polynucleotides with different sequences and, second, with a mixture containing DNA, RNA and two types of DNA:RNA hybrid structures. Netropsin, ethidium, daunorubicin and actinomycin, ligands with known sequence preferences, were used to illustrate the method. The applicability of the approach to oligonucleotide systems is illustrated by the use of simple ternary and binary mixtures of defined sequence deoxyoligonucleotides challenged by the bisanthracycline WP631. The simple mixtures described here provide proof of principle of the assay and pave the way for the development of more sophisticated mixtures for rapidly screening the selectivity of new nucleic acid binding compounds.     

The effect of different fixatives on chromatin: Cytochemical and ultrastructural approaches

Summary This study explores the effects of two types of fixative on chromatin. The first type (acrolein, glutaraldehyde) engenders a high degree of ultrastructural preservation. The other type are fixatives that are widely used in cytochemistry and cytogenetics (acetic acid, 31 by vol. methanol-acetic acid, methanol alone, formaldehyde).Lymphocytes of adult rats so-fixedin vitro were prepared for electron microscopy or microdensitometric evaluations of smears. Assessments were made of variations in their total protein, nuclear basic protein and DNA contents. DNA was determined both as Feulgen-positive material and by its binding of intercalating dyes (Methyl Green, specific for double-stranded polynucleotides).Our results showed that some fixatives break up the chromatin organization by acting on particular components of chromatin fibres. They can thus be considered to be destructive agentsin situ. In addition, a revaluation of some aldehyde fixatives is proposed for both ultrastructural and cytochemical research.     

Efficiency of DNA-histone crosslinking induced by saturated and unsaturated aldehydes in vitro.

Using a filter-binding assay based on precipitation of pUC13 plasmid DNA bound to calf-thymus histones, we have determined the efficiency of formation of DNA-protein crosslink formation induced by several aldehyde compounds in vitro. Formaldehyde, glutaraldehyde and acrolein were the most potent, causing 1 crosslink per 2.7 kbp of DNA at 1.5, 8 and 150 microM, respectively. All other compounds tested gave 1 crosslink per plasmid molecule in the mM concentration range as follows: acetaldehyde, 115 mM; propionaldehyde, 295 mM; butyraldehyde, 360 mM; crotonaldehyde, 8.5 mM; trans-2-pentenal, 6.3 mM. Significant decreases in the efficiency of DPXL formation were observed with monofunctional aldehydes of higher carbon chain length. For example, the concentration of formaldehyde needed to give 1 crosslink per molecule was almost 10(5) times less than that of acetaldehyde. Acetaldehyde differs from formaldehyde only by one saturated carbon. The presence of an unsaturated bond between the 2-3 carbons improved the potential for crosslink formation. For example, acrolein was over 500-fold more potent than propionaldehyde. Glutaraldehyde was almost as potent as formaldehyde, indicating that the bifunctional nature of this 5-carbon saturated aldehyde may be crucial to its high efficiency of DNA-protein crosslinking.     

LNA/DNA chimeric oligomers mimic RNA aptamers targeted to the TAR RNA element of HIV-1

One of the major limitations of the use of phosphodiester oligonucleotides in cells is their rapid degradation by nucleases. To date, several chemical modifications have been employed to overcome this issue but insufficient efficacy and/or specificity have limited their in vivo usefulness. In this work conformationally restricted nucleotides, locked nucleic acid (LNA), were investigated to design nuclease resistant aptamers targeted against the HIV-1 TAR RNA. LNA/DNA chimeras were synthesized from a shortened version of the hairpin RNA aptamer identified by in vitro selection against TAR. The results indicate that these modifications confer good protection towards nuclease digestion. Electrophoretic mobility shift assays, thermal denaturation monitored by UV-spectroscopy and surface plasmon resonance experiments identified LNA/DNA TAR ligands that bind to TAR with a dissociation constant in the low nanomolar range as the parent RNA aptamer. The crucial G, A residues that close the aptamer loop remain a key structural determinant for stable LNA/DNA chimera–TAR complexes. This work provides evidence that LNA modifications alternated with DNA can generate stable structured RNA mimics for interacting with folded RNA targets.     

The importance of fixation procedures on DNA template and its suitability for solution-phase polymerase chain reaction and PCR in situ hybridization

Summary Conventional solution-phase polymerase chain reaction (PCR) and in situ PCR/PCR in situ hybridization are powerful tools for retrospective analysis of fixed paraffin wax-embedded material. Amplification failure using these techniques is now encountered in some centres using archival fixed tissues. Such ailures may not only be due to absent target DNA sequences in the tissues, but may be a direct effect of the type of fixative, fixation time and/or fixation temperature used. The type of nucleic acid extraction procedure applied will also influence amplification results. This is particularly true with in situ PCR/PCR in situ hybridization.To examine these effects in solution-phase PCR, -globin gene was amplified in 100 mg pieces of tonsillar tissue fixed in Formal saline, 10% formalin, neutral buffered formaldehyde, Carnoy's, Bouin's, buffered formaldehyde sublimate, Zenker's, Helly's and glutaraldehyde at 0 to 4°C, room temperature and 37°C fixation temperatures and for fixation periods of 6, 24, 48 and 72 hours and 1 week. DNA extraction procedures used were simple boiling and 5 days' proteinase K digestion at 37°C. Amplified product was visible primarily yet variably from tissue fixed in neutral buffered formaldehyde and Carnoy's, whereas fixation in mercuric chloride-based fixatives produced consistently negative results. Room temperature and 37°C fixation temperature appeared most conducive to yielding amplifiable DNA template. Fixation times of 24 and 48 hours in neutral buffered formaldehyde and Carnoy's again favoured amplification.Fixed SiHa cells (containing 1–2 copies of HPV 16) were examined using PCR in situ hybridization for the amplification of HPV 16. Discrete and diffuse amplification signals were obtained. Neutral buffered formaldehyde fixation for 12–24 hours yielded amplifiable material suitable for use with PCR in situ hybridization. Overall amplification success within cellular preparations was 40%, with non-specific background staining also seen. Possible technical problems encountered with PCR in situ hybridization are discussed.     

Analysis of nucleic acid binding by a recombinant translin-trax complex

Translin is a highly conserved mammalian RNA and DNA-binding protein involved in DNA recombination and RNA trafficking. Crystal structures of mouse and human translin have been solved, but do not provide information about nucleic acid binding or recognition. Translin has a partner protein, translin-associated factor x (trax), which is believed to regulate translin’s subcellular locale and affinity for certain RNA and DNA sequences. Here we present a comparative study of recombinant translin and translin-trax complex binding to specific RNA and DNA sequences. It was observed that translin preferentially binds to G-rich RNA sequences whereas translin-trax preferentially binds G-rich DNA sequences. Translin can bind mRNA sequences with sub-micromolar K_d values, and the complex with trax can bind G-rich DNA with similar affinity. We conclude that trax acts to regulate translin’s RNA and DNA binding affinities as part of a cellular RNA trafficking mechanism.     

Effect of enzymatic methylation on the chemical,physical, and biological properties of DNA

DNA methylase was partially purified from Escherichia coli W and used to methylate DNA from Bacillus subtilis and bacteriophage φ105. The former DNA was methylated 1.17% and the latter 0.87%. The products were 6-methyladenine (85%) and 5-methylcytosine (15%) in both cases. The methylated DNA was stable toward depurination and viscosity loss at elevated temperatures. Methylation led to a 50% decrease in transforming activity in two strains of B. subtilis and no change in a third strain. The ability of phage φ105 DNA to rescue a defective phage strain was decreased 50% by methylation. No changes were observed in the ability of methylated DNA to serve as a template for DNA polymerase or RNA polymerase. The pattern of cleavage of DNA by a variety of restriction endonucleases was not affected by methylation. There were no changes in the physicochemical properties of DNA on methylation as measured by hyperchromicity on heating, formaldehyde denaturation, viscosity, and sedimentation.