In situ DNA-RNA hybridization using in vivo bromodeoxyuridine-labeled DNA probe

An in vivo 5'-bromodeoxyuridine (BrdUrd) labeled DNA probe was used for in situ DNA-RNA hybridization. BrdUrd was incorporated into plasmid DNA by inoculating E. coli with Luria-Bertani (LB) culture medium containing 500 mg/L of BrdUrd. After purification of the plasmid DNA, specific probes of the defined DNA fragments, which contained the cloned insert and short stretches of the vector DNA, were generated by restriction endonuclease. The enzymatic digestion pattern of the BrdUrd-labeled plasmid DNA was the same as that of the non-labeled one. BrdUrd was incorporated in 15%-20% of the total DNA, that is, about 80% of the thymidine was replaced by BrdUrd. Picogram amounts of the BrdUrd-labeled DNA probe itself and the target DNA were detectable on nitrocellulose filters in dot-blot spot and hybridization experiments using a peroxidase/diaminobenzidine combination. The BrdUrd-labeled DNA probe was efficiently hybridized with both single stranded DNA on nitrocellulose filters and cellular mRNA in in situ hybridization experiments. Through the reaction with BrdUrd in single stranded tails, hybridized probes were clearly detectable with fluorescent microscopy using a FITC-conjugated monoclonal anti-BrdUrd antibody. The in vivo labeling method did not require nick translation steps or in vitro DNA polymerase reactions. Sensitive, stable and efficient DNA probes were easily obtainable with this method.     

In situ DNA-RNA hybridization using in vivo bromodeoxyuridine-labeled DNA probe

Summary An in vivo 5-bromodeoxyuridine (BrdUrd) labeled DNA probe was used for in situ DNA-RNA hybridization. BrdUrd was incorporated into plasmid DNA by inoculating E. coli with Luria-Bertani (LB) culture medium containing 500 mg/L of BrdUrd. After purification of the plasmid DNA, specific probes of the defined DNA fragments, which contained the cloned insert and short stretches of the vector DNA, were generated by restriction endonuclease. The enzymatic digestion pattern of the BrdUrd-labeled plasmid DNA was the same as that of the non-labeled one. BrdUrd was incorporated in 15%–20% of the total DNA, that is, about 80% of the thymidine was replaced by BrdUrd. Picogram amounts of the BrdUrd-labeled DNA probe itself and the target DNA were detectable on nitrocellulose filters in dot-blot spot and hybridization experiments using a peroxidase/diaminobenzidine combination. The BrdUrd-labeled DNA probe was efficiently hybridized with both single stranded DNA on nitrocellulose filters and cellular mRNA in in situ hybridization experiments. Through the reaction with BrdUrd in single stranded tails, hybridized probes were clearly detectable with fluorescent microscopy using a FITC-conjugated monoclonal anti-BrdUrd antibody. The in vivo labeling method did not require nick translation steps or in vitro DNA polymerase reactions. Sensitive, stable and efficient DNA probes were easily obtainable with this method.     

Hairpin DNA probe based electrochemical biosensor using methylene blue as hybridization indicator

In this paper, a label-free, rapid and simple method was proposed to study the hybridization specificity of hairpin DNA probe using methylene blue (MB) as a hybridization indicator. Thiolated hairpin DNA probe was immobilized on the gold electrode by self-assembly. The voltammetric signals of MB were investigated at these modified electrodes by means of cyclic voltammetry (CV) detection. Single-base mutation oligonucleotide and random oligonucleotide can be easily discriminated from complementary target DNA. The effect of mismatch position in target DNA was investigated. Experimental results showed that mutation in the center of target DNA had greatest effect on the hybridization with hairpin DNA probe. The relationship between electrochemical responses and DNA target concentration was also studied. The reduction current of MB intercalation decreased with increasing the concentration of target DNA. Taken together, these experiments demonstrate that the hybridization indicator MB provides great promise for rapid and specific measurement of target DNA.     

Applications of universal probe on DNA hybridization

A convenient method for DNA hybridization termed Universal probe is described which is based on the principle of sandwich hybridization. This system consists of two probes: primary probe which is single-stranded DNA prepared from a chimeric phage-plasmid vector containing the complementary sequence to a target; and labeled secondary probe which has an opposite strand of the primary probe without the complementary sequence. By use this universal probe human beta-globin gene was able to be detected on Southern blots of genomic DNA. A potential advantage of this method is that the single-stranded primary probe is prepared easily by the chimeric phage-plasmid vector system and tedious labeling is not needed each time.     

DNA hybridization probe for the Pseudomonas fluorescens group

Plasmid pHF360 was constructed from cloned rRNA genes (rDNA) of Pseudomonas aeruginosa and used as hybridization probe for the Pseudomonas fluorescens group. The probe was tested by dot and in situ colony hybridizations to chromosomal DNAs from a wide variety of organisms. pHF360 DNA hybridized exclusively to chromosomal DNAs from bacteria representing the P. fluorescens group and separated them clearly from all other bacteria tested in the present study. Determination of the nucleotide sequence of the cloned DNA showed that it is a fragment from a 23S rRNA gene of P. aeruginosa. It was compared with the published 23S RNA sequence from Escherichia coli.     

Development of a DNA probe using differential hybridization to detect the fish pathogenVibrio anguillarum

The fish pathogenVibrio anguillarum causes significant economic losses in commercially cultured fish species worldwide. At present, identification ofV. anguillarum requires conventional isolation and culturing techniques. Using differential hybridization, a 310 base pairV. anguillarum-specific DNA fragment was isolated for use as a probe. In specificity studies against 19 different bacterial species, including twoVibrio sp. and fish pathogens, and 223 marine bacterial isolates, the probe hybridized exclusively toV. anguillarum strains. The probe also strongly hybridizes to 7 of 9 serotypes tested, with serotype 09 giving a weak probe reaction and serotype O7 negative. The probe allows rapid and accurate detection of both pathogenic and environmental strains ofV. anguillarum.     

Islet surface modification with urokinase through DNA hybridization

Transplantation of islets of Langerhans (islets) has been proposed as a safe, effective approach to treating patients with insulin-dependent diabetes mellitus (type I diabetes). It has been reported, however, that many islets are lost in the early phase after intraportal transplantation by instant blood coagulation-mediated inflammatory reactions. In this study, DNA hybridization was applied to conjugate the fibrinolytic enzyme urokinase on the islet surface. We synthesized amphiphilic polymers, PEG-lipids carrying oligo(dT)(20) (oligo(dT)(20)-PEG-lipid; PEG MW = 5000) and urokinase (UK) carrying oligo(dA)(20). The oligo(dT)(20)-PEG-lipid was spontaneously incorporated into the cell membrane through interactions between the hydrophobic parts of the PEG-lipids and the lipid bilayer, and UK was conjugated on the cell surface through DNA hybridization between oligo(dT)(20) on the cell and complementary oligo(dA)(20) on the UK. The activity of UK was maintained on the islet surface. The surface modification with UK did not influence islet morphology or islet ability to secrete insulin in response to changes in glucose concentration. No practical volume increase was observed with our method, indicating that islet graft loss could be suppressed at the early stage of intraportal islet transplantation.     

DNA hybridization probe for the Pseudomonas fluorescens group.

Plasmid pHF360 was constructed from cloned rRNA genes (rDNA) of Pseudomonas aeruginosa and used as hybridization probe for the Pseudomonas fluorescens group. The probe was tested by dot and in situ colony hybridizations to chromosomal DNAs from a wide variety of organisms. pHF360 DNA hybridized exclusively to chromosomal DNAs from bacteria representing the P. fluorescens group and separated them clearly from all other bacteria tested in the present study. Determination of the nucleotide sequence of the cloned DNA showed that it is a fragment from a 23S rRNA gene of P. aeruginosa. It was compared with the published 23S RNA sequence from Escherichia coli.     

The effect of surface probe density on DNA hybridization

The hybridization of complementary strands of DNA is the underlying principle of all microarray-based techniques for the analysis of DNA variation. In this paper, we study how probe immobilization at surfaces, specifically probe density, influences the kinetics of target capture using surface plasmon resonance (SPR) spectroscopy, an in situ label-free optical method. Probe density is controlled by varying immobilization conditions, including solution ionic strength, interfacial electrostatic potential and whether duplex or single stranded oligonucleotides are used. Independent of which probe immobilization strategy is used, we find that DNA films of equal probe density exhibit reproducible efficiencies and reproducible kinetics for probe/target hybridization. However, hybridization depends strongly on probe density in both the efficiency of duplex formation and the kinetics of target capture. We propose that probe density effects may account for the observed variation in target-capture rates, which have previously been attributed to thermodynamic effects.     

Large scale preparation of DNA for vast DNA excess hybridization

A method for the preparation of relatively large quantities of sonicated DNA for use in the vast DNA excess hybridization technique is reported. The procedure, applied here to rat liver DNA, involves centrifugation of DNA from sonicated nuclei to equilibrium in a CsCl gradient, RNase and pronase digestion, and phenol extraction. Compared with DNA purified by the Marmur procedure, the product has a lower contamination with protein and RNA, takes about one third the time to prepare, and has better hybridization characteristics.     

Enhanced photoelectrochemical method for linear DNA hybridization detection using Au-nanopaticle labeled DNA as probe onto titanium dioxide electrode

A photoelectrochemical method was proposed to detect DNA hybridization using Au nanoparticle modified DNA as one probe on TiO2 substrate, in which the TiO2 substrate was used not only as DNA anchors but also as the signal transducers. Hybridization between the probe and the target DNA oligonucleotides was confirmed by the decreased photocurrent of the TiO2 electrode. Compared with non-label probe, Au nanoparticles enhanced the photocurrent shifts after the hybridization. The photocurrent decreased with increasing the concentration of target DNA, indicating that this method could be used for quantitative measurements, and the discrimination of the complementary from mismatched DNA. Furthermore, the hybridization binding constant was obtained and photocurrent generation mechanism was discussed. The major advantages of this photochemical method are speed, simplicity and excellent specificity. This method provides a platform for studying a wide variety of biological processes using photoelectrochemical method.     

Quantitation of casein messenger ribonucleic acid sequences using a specific complementary DNA hybridization probe.

Two highly purified rat casein mRNA fractions were used as templates to synthesize complementary DNA (cDNA) hybridization probes using RNA-directed DNA polymerase isolated from avian myeloblastosis virus. Both of the probes selectively hybridized to RNA isolated from lactating mammary tissue, but not to poly(adenylic acid)-containing rat liver RNA. An analysis of the kinetics of hybridization of the cDNA derived from the 15S casein mRNA (cDNA12S) with their individual mRNA templates indicated that greater than 90% hybridization occurred over a R0t range of one and one-half logs with R0t 1/2 values of 0.0023 and 0.0032 mol s l.-1, respectively. Compared with the total RNA isolated from lactating mammary tissue, these values represented a 166- and 245-fold purification, respectively, of these individual mRNA fractions. Using the 15S casein mRNA as a template, two probes of different lengths and specific activities were synthesized. The deoxyribonucleotide and mRNA concentrations and the temperature of incubation were optimized to obtain either a high specific activity cDNA probe, 330 nucleotides long, which represented approximately 25% of the mRNA or a lower specific activity preparation containing some complete cDNA copies, 1300 nucleotides in length. The Tm of the longer cDNA15S-15S mRNA hybrid was 88.5 degrees C, while that of the short cDNA15S-RNA hybrid was 82.5 degrees C. Following this initial characterization, the cDNA15S probe was utilized for three separate determinations: (1) Analysis of the sequence divergence between mouse and rat casein mRNAs. It was observed that the rate of hybridization of heterologous rat cDNA15S-mouse casein mRNA was only 20% that of the homologous rat cDNA15S-rat casein mRNA hybridization. The resulting heterologous hybrid displayed approximately 17% mismatching compared with the homologous hybrid. (2) Determination of the gene dosage for casein mRNA in normal and malignant mammary cells. In this study, an analysis of the kinetics of hybridization of the high specific activity cDNA15S probe with an excess of DNA isolated from lactating mammary tissue, carcinogen-induced mammary tumors, or rat liver indicated that casein mRNA was transcribed from the nonlification or deletion was observed during tumor formation or the process of mammary differentiation. (3) Quantitation of casein mRNA sequences during normal mammary gland development. RNA excess hybridizations were performed using RNA extracted from either pregnant, lactating, or regressed rat mammary tissue. The concentration of casein mRNA molecules/alveolar cell was found to increase 12-fold from 5 days of pregnancy until 8 days of lactation and then declined to approximately 2% of the maximal level of 79 000 molecules/cell by 7 days after weaning. A coordinate increase was observed in casein mRNA sequences detected by cDNA hybridization and mRNA activity measured in a cell-free translation assay.     

DNA hybridization assays using metal-enhanced fluorescence

We describe a new approach to DNA hybridization assays using metal-enhanced fluorescence. Thiolated oligonucleotides were bound to silver particles on a glass substrate. Addition of a complementary fluorescein-labeled oligonucleotide resulted in a dramatic time-dependent 12-fold increase in fluorescence intensity during hybridization. Proximity to silver particles resulted in a decreased fluorescence lifetime. This effect is thought to be the result of enhanced fluorescence from fluorescein near metallic silver particles. Hybridization could thus be measured from the decay kinetics of the emission, which can be measured independently from the emission intensity. These results suggest the use of silver particles as a general approach to measure DNA hybridization as a method to increase the sensitivity of DNA detection.     

DNA computing using single-molecule hybridization detection

DNA computing aims at using nucleic acids for computing. Since micromolar DNA solutions can act as billions of parallel nanoprocessors, DNA computers can in theory solve optimization problems that require vast search spaces. However, the actual parallelism currently being achieved is at least a hundred million-fold lower than the number of DNA molecules used. This is due to the quantity of DNA molecules of one species that is required to produce a detectable output to the computations. In order to miniaturize the computation and considerably reduce the amount of DNA needed, we have combined DNA computing with single-molecule detection. Reliable hybridization detection was achieved at the level of single DNA molecules with fluorescence cross-correlation spectroscopy. To illustrate the use of this approach, we implemented a DNA-based computation and solved a 4-variable 4-clause instance of the computationally hard Satisfiability (SAT) problem.     

Fluorescent in-situ hybridization of cattle and sheep chromosomes with cloned human fragile-X DNA

An extensive study on spontaneous and 5-Fluorodeoxyuridine induced fragile sites identified Xq31 in cattle (Bos taurus) and (Xq24, Xq26) in sheep (Ovis aries) in addition to several autosomal fragile sites (under publication). A ZOO-FISH study using three cloned human fragile-X probes with CCG/CGG_n trinucleotide repeat sequence was carried out to determine homology between human and bovine fragile-X. The hybridisation results showed only a weak signal on a human chromosome that was not an X with all three fragile site probes. No signals were detected in sheep chromosomes. The signal of all three human fragile-X probes on cattle chromosomes was however, medium-prominent sub-centromeric signal on two homologues. BrdU administration in 12 h before harvesting identified these homologues to be chromosome number 5. In addition retrospective slides of cattle and sheep chromosomes used for fragile site studies showed no signals whatsoever. It was therefore concluded that no homology existed between human and bovine fragile-X.     

In situ hybridization to metaphase chromosomes in six species ofPhaseolus andVigna using ribosomal DNA as the probe

In situ hybridization with a biotin-labeled rice ribosomal DNA (rDNA) probe to the somatic metaphase chromosomes of six species ofPhaseolus andVigna (P. angularis, P. calcaratus, P. coccineus, P. vulgaris, V. sesquipedalis andV. sinensis) was done to determine the sites of rDNA. Hybridization signals were present in the terminal and subterminal chromosome regions of each of the six species. The number of rDNA sites was two inP. angularis andP. calcaratus, four inP. coccineus andP. vulgaris, and six inV. sesquipedalis andV. sinensis.     

Microwave irradiation-stimulated in situ hybridization procedure with biotinylated DNA probe.

A microwave-stimulated in situ hybridization technique using biotin-labeled DNA probe is described. Both hybridization reaction and the detection of the biotin label (with a alkaline phosphatase or immunofluorescence method) has been performed in the microwave oven. All procedures are completed within one hour. The described method was applied for identification of nucleic acid sequences of human immunodeficiency virus in human cell lines. The resolution and the intensity of the signal are as good as from a standard technique with overnight incubation of the probe. Because of the simplicity and speed of the technique, this procedure can be used in a number of other applications.     

Comparison of three nonradioactive and a radioactive DNA probe for the detection of target DNA by DNA hybridization

The specificity and sensitivity of three methods for the preparation and detection of nonradioactive probe DNA (biotin-nick translation, biotin-photolabel, and antigen-chemical linkage) were evaluated and compared with a nick-translated³²P-labeled DNA probe in DNA hybridization studies. The DNA probes were prepared from a restriction fragment (HindIII-3) from bacteriophage P1 DNA, and target DNA consisted of purified phage P1 DNA or P1 prophage DNA in lysogens ofEscherichia coli. A probe concentration of 50 ng/ml resulted in clear detection with the three nonradioactiveHindIII-3 DNA probes, whereas the specificity of the³²P-HindIII-3 DNA probe was satisfactory at a concentration of 25 ng/ml. However, the detection of false positives was greater with the³²P-labeled probe. The sensitivity of the radiolabeled DNA probe was marginally greater than that of the nonradioactive probes in dot blot hybridizations with purified phage P1 DNA. However, when the preparation time, ease of use, safety, duration of storage, and expense were compared for the four methods of labeling, the nonradiolabeled probes were generally superior to the radiolabeled probe.