Smart probe: a novel fluorescence quenching-based oligonucleotide probe carrying a fluorophore and an intercalator.

A novel probe (Smart probe) has been developed for nucleic acid detection. The smart probe is an oligodeoxyribonucleotide carrying a fluorophore and an intercalator internally. Fluorescence of the smart probe is quenched by the intercalator in the absence of target sequence. While upon hybridization the probe emits greater fluorescence due to the interference of quenching by intercalation. The smart probe has been shown to recognize a single base mismatch in the double-stranded form without utilizing thermal stability difference of hybrids.     

Protein-free parallel triple-stranded DNA complex formation

A 14 nt DNA sequence 5′-AGAATGTGGCAAAG-3′ from the zinc finger repeat of the human KRAB zinc finger protein gene ZNF91 bearing the intercalator 2-methoxy,6-chloro,9-amino acridine (Acr) attached to the sugar–phosphate backbone in various positions has been shown to form a specific triple helix (triplex) with a 16 bp hairpin (intramolecular) or a two-stranded (intermolecular) duplex having the identical sequence in the same (parallel) orientation. Intramolecular targets with the identical sequence in the antiparallel orientation and a non-specific target sequence were tested as controls. Apparent binding constants for formation of the triplex were determined by quantitating electrophoretic band shifts. Binding of the single-stranded oligonucleotide probe sequence to the target led to an increase in the fluorescence anisotropy of acridine. The parallel orientation of the two identical sequence segments was confirmed by measurement of fluorescence resonance energy transfer between the acridine on the 5′-end of the probe strand as donor and BODIPY-Texas Red on the 3′-amino group of either strand of the target duplex as acceptor. There was full protection from OsO₄-bipyridine modification of thymines in the probe strand of the triplex, in accordance with the presumed triplex formation, which excluded displacement of the homologous duplex strand by the probe–intercalator conjugate. The implications of these results for the existence of protein-independent parallel triplexes are discussed.     

Spectral properties and DNA targeting features of a thiazole orange-peptide bioconjugate

The molecular recognition features of a DNA-sensitive fluorescent bioconjugate capable of targeting a specific DNA sequence with high efficiency are described. The bioconjugate combines a polypeptide from the Tc3 transposase DNA-binding domain with the dsDNA-sensitive fluorophore thiazole orange. Fluorescence spectroscopy and circular dichroism reveal that the polypeptide moiety determines the DNA sequence specificity as the intercalating dye makes nonspecific contributions to binding affinity. The conjugated thiazole orange is able to intercalate and fluoresce when the peptide binds at concentrations where little fluorescence is observed from either the bioconjugate alone or the bioconjugate mixed with DNA lacking the target sequence. Fluorescence studies indicate this molecular probe is sequence specific, binds the native Tc3 DNA target sequence with nanomolar affinity (KD approximately 15 nM), and is able to discriminate multiple point mutations in the cognate DNA site. The attachment of a sequence-specific binding peptide onto a functional probe provides a viable strategy for construction of synthetic enzymes and repressors, and facilitates dynamic studies of protein-DNA interactions.     

Combination probes with intercalating anchors and proximal fluorophores for DNA and RNA detection

A new class of modified oligonucleotides (combination probes) has been designed and synthesised for use in genetic analysis and RNA detection. Their chemical structure combines an intercalating anchor with a reporter fluorophore on the same thymine nucleobase. The intercalator (thiazole orange or benzothiazole orange) provides an anchor, which upon hybridisation of the probe to its target becomes fluorescent and simultaneously stabilizes the duplex. The anchor is able to communicate via FRET to a proximal reporter dye (e.g. ROX, HEX, ATTO647N, FAM) whose fluorescence signal can be monitored on a range of analytical devices. Direct excitation of the reporter dye provides an alternative signalling mechanism. In both signalling modes, fluorescence in the unhybridised probe is switched off by collisional quenching between adjacent intercalator and reporter dyes. Single nucleotide polymorphisms in DNA and RNA targets are identified by differences in the duplex melting temperature, and the use of short hybridization probes, made possible by the stabilisation provided by the intercalator, enhances mismatch discrimination. Unlike other fluorogenic probe systems, placing the fluorophore and quencher on the same nucleobase facilitates the design of short probes containing multiple modifications. The ability to detect both DNA and RNA sequences suggests applications in cellular imaging and diagnostics.     

Synthesis, photophysical effects, and DNA targeting properties of oxazole yellow-peptide bioconjugates

The design of a dsDNA-sensitive fluorescent bioconjugate capable of targeting a specific DNA sequence with high efficiency is described. The bioconjugate has the molecular recognition features of the polypeptide from a DNA-binding protein and the dsDNA-dependent fluorescence of an intercalating dye. The DNA sequence selectivity of the probe was characterized, as were the changes in photophysical properties of the dye upon covalent linkage to the peptide to assess whether such bioconjugates could function as molecular probes of gene sequences. The oxazole yellow-peptide bioconjugate exhibits DNA recognition and binding affinity comparable to the native Hin recombinase protein. Examination of photophysical effects to dye conjugation indicates a negligible affect on the fluorescence quantum yield. Fluorescence studies indicate this molecular probe is useful to determine the presence of a given DNA target sequence and gives negligible fluorescence in the absence of a given target site. Using the synthetic route described here, bioconjugates could be designed using different combinations of DNA recognition polypeptides and cyanine dyes to generate an array of sequence specific and wavelength specific probes.     

Fast high-resolution mapping of long fragments of genomic DNA based on single-molecule detection

Here we describe bacterial genotyping by direct linear analysis (DLA) single-molecule mapping. DLA involves preparation of restriction digest of genomic DNA labeled with a sequence-specific fluorescent probe and stained nonspecifically with intercalator. These restriction fragments are stretched one by one in a microfluidic device, and the distribution of probes on the fragments is determined by single-molecule measurement of probe fluorescence. Fluorescence of the DNA-bound intercalator provides information on the molecule length. Because the probes recognize short sequences, they encounter multiple cognate sites on 100- to 300-kb-long DNA fragments. The DLA maps are based on underlying DNA sequences of microorganisms; therefore, the maps are unique for each fragment. This allows fragments of similar lengths that cannot be resolved by standard DNA sizing techniques to be readily distinguished. DNA preparation, data collection, and analysis can be carried out in as little as 5 h when working with monocultures. We demonstrate the ability to discriminate between two pathogenic Escherichia coli strains, O157:H7 Sakai and uropathogenic 536, and we use DLA mapping to identify microorganisms in mixtures. We also introduce a second color probe to double the information used to distinguish molecules and increase the length range of mapped fragments.     

Screening for oligonucleotide binding affinity by a convenient fluorescence competition assay.

A competitive homogeneous quenched fluorescence assay system is described for the high throughput screening of DNA conjugates that bind to single-stranded DNA. Fluorescence signal is generated by competitive binding of the sample molecule to a target strand labelled with a quencher probe, which is otherwise hybridised to a complementary strand containing a fluorescent probe. Thus fluorescence generated is related to the affinity of the sample. Competitive analysis of a number of peptide-oligonucleotide conjugates gave data that correlated well with the corresponding UV melting data. The assay will be useful for screening of large numbers of potential single-stranded binding molecules.     

A pitfall in using BODIPY dyes to label lipid droplets for fluorescence microscopy

The lipid droplet (LD) has become a focus of intense research. Fluorescence labeling is indispensable for the cell biological analysis of the LD, and a lipophilic fluorescence dye, BODIPY 493/503, which emits bright green fluorescence has been used extensively for LD labeling. The dye is convenient for double fluorescence labeling, but we noticed that it emits red fluorescence under certain conditions, which could lead to erroneous interpretations. We propose a protocol to preclude such a possibility.     

Extension of the range of DNA sequences available for triple helix formation: stabilization of mismatched triplexes by acridine-containing oligonucleotides.

Triple helix formation usually requires an oligopyrimidine*oligopurine sequence in the target DNA. A triple helix is destabilized when the oligopyrimidine*oligopurine target contains one (or two) purine*pyrimidine base pair inversion(s). Such an imperfect target sequence can be recognized by a third strand oligonucleotide containing an internally incorporated acridine intercalator facing the inverted purine*pyrimidine base pair(s). The loss of triplex stability due to the mismatch is partially overcome. The stability of triplexes formed at perfect and imperfect target sequences was investigated by UV thermal denaturation experiments. The stabilization provided by an internally incorporated acridine third strand oligonucleotide depends on the sequences flanking the inverted base pair. For triplexes containing a single mismatch the highest stabilization is observed for an acridine or a propanediol tethered to an acridine on its 3'-side facing an inverted A*T base pair and for a cytosine with an acridine incorporated to its 3'-side or a guanine with an acridine at its 5'-side facing an inverted G*C base pair. Fluorescence studies provided evidence that the acridine was intercalated into the triplex. The target sequences containing a double base pair inversion which form very unstable triplexes can still be recognized by oligonucleotides provided they contain an appropriately incorporated acridine facing the double mismatch sites. Selectivity for an A*T base pair inversion was observed with an oligonucleotide containing an acridine incorporated at the mismatched site when this site is flanked by two T*A*T base triplets. These results show that the range of DNA base sequences available for triplex formation can be extended by using oligonucleotide intercalator conjugates.     

Sequence dependence of fluorescence emission and quenching of doubly thiazole orange labeled DNA: effective design of a hybridization-sensitive probe

We have designed a doubly thiazole orange labeled nucleoside showing high fluorescence intensity for a hybrid with the target DNA and effective quenching for a single-stranded state. Knowing how much the fluorescence emission and quenching of this probe depend on the probe sequence and why there is such a sequence dependence is important for effective probe design, we synthesized more than 30 probe sequences and measured their fluorescence intensities. When the probe hybridized with the target DNA strands, there was strong emission, whereas the emission intensity was much weaker before hybridization; however, self-dimerization of probes suppressed fluorescence quenching. In particular, the G/C base pairs neighboring the labeled nucleotide in a self-dimeric structure resulted in a low quenching ability for the probe before hybridization. On the other hand, mismatched base pair formation around the labeled site decreased the fluorescence intensity because the neighboring sequence is the binding site of the tethered thiazole orange dyes. The hybridization enhanced the fluorescence of the probe even when the labeled nucleotide was located at the end of the probe strand; however, the partial lack of duplex structure resulted in a decrease in the fluorescence intensity of the hybrid.     

Characterization and applications of CataCleave probe in real-time detection assays

Cycling probe technology (CPT), which utilizes a chimeric DNA-RNA-DNA probe and RNase H, is a rapid, isothermal probe amplification system for the detection of target DNA. Upon hybridization of the probe to its target DNA, RNase H cleaves the RNA portion of the DNA/RNA hybrid. Utilizing CPT, we designed a catalytically cleavable fluorescence probe (CataCleave probe) containing two internal fluorophores. Fluorescence intensity of the probe itself was weak due to F?rster resonance energy transfer. Cleavage of the probe by RNase H in the presence of its target DNA caused enhancement of donor fluorescence, but this was not observed with nonspecific target DNA. Further, RNase H reactions with CataCleave probe exhibit a catalytic dose-dependent response to target DNA. This confirms the capability for the direct detection of specific target DNA through a signal amplification process. Moreover, CataCleave probe is also ideal for detecting DNA amplification processes, such as polymerase chain reaction (PCR) and isothermal rolling circle amplification (RCA). In fact, we observed signal enhancement proportional to the amount of RCA product formed. We were also able to monitor real-time PCR by measuring enhancement of donor fluorescence. Hence, CataCleave probe is useful for real-time monitoring of both isothermal and temperature-cycling nucleic acid amplification methods.     

Selective quenching of fluorescence from unbound oligonucleotides by gold nanoparticles as a probe of RNA structure

Binding of small oligonucleotides to the periphery of folded RNA can provide insight into the secondary structure of complex RNA in solution. To discriminate between bound and unbound fluorescein-labeled 2'-O-methyl RNA probes, we use ionically coated gold nanoparticles to selectively adsorb unbound probes and quench their fluorescence. The target is the 3' untranslated region of Bombyx mori R2 RNA. Fluorescence indicates that R2 sequences complementary to some of the probes are accessible for binding in the three-dimensional structure. Hybridization occurs under homogeneous conditions in the absence of the gold nanoparticles so that steric issues associated with chip-based assays are avoided. The assay is compatible with well plate formats, takes less than 5 min, and requires only 2 pmol or less of unlabeled target RNA per probe sequence tested.     

DNA detection by strand displacement amplification and fluorescence polarization with signal enhancement using a DNA binding protein.

Strand displacement amplification (9SDA) is an isothermal in vitro method of amplifying a DNA sequence prior to its detection. We have combined SDA with fluorescence polarization detection. A 5'-fluorescein-labelled oligodeoxynucleotide detector probe hybridizes to the amplification product that rises in concentration during SDA and the single- to double strand conversion is monitored through an increase in fluorescence polarization. Detection sensitivity can be enhanced by using a detector probe containing an EcoRI recognition sequence at its 5'-end that is not homologous to the target sequence. During SDA the probe is converted to a fully double-stranded form that specifically binds a genetically modified form of the endonuclease EcoRI which lacks cleavage activity but retains binding specificity. We have applied this SDA detection system to a target sequence specific for Mycobacterium tuberculosis.     

Simple SNP typing assay using a base-discriminating fluorescent probe

We have developed a new concept involving a single-step homogeneous method for single-nucleotide polymorphism (SNP) typing. In this method, a probe containing base-discriminating fluorescent (BDF) bases is added to a sample solution. BDF base-containing DNA usually shows only a weak fluorescence, but emits a strong blue fluorescence when it recognizes a target base at a specific site in a hybridized strand. By utilizing this feature, a simple mix-and-read SNP typing assay was achieved without any tedious probe-designing or washing processes for exclusion of hybridization error or any addition of DNA-modifying enzymes. This is very different from conventional methods. We simultaneously analyzed a number of samples with ease, with a high accuracy, using our BDF assay.     

Comparing mono- and divalent DNA groove binding cyanine dyes -- binding geometries, dissociation rates, and fluorescence properties

The unsymmetrical cyanine dyes BOXTO-PRO and BOXTO-MEE were derived from the DNA groove binder BOXTO, by adding a positively charged or a non-ionic hydrophilic tail to BOXTO, respectively. The main objective was to obtain more efficient DNA probes, for instance in electrophoresis and microscopy, by slowing down the dissociation of BOXTO from DNA. The interactions with mixed sequence DNA was studied with fluorescence and absorbance spectroscopy, stopped-flow dissociation and gel electrophoresis. Both the derivatives are groove bound as BOXTO, and have similar fluorescence properties when bound to mixed sequence DNA in free solution. BOXTO-PRO exhibits a slower dissociation than BOXTO from DNA, whereas the dissociation rate for BOXTO-MEE is faster and, unexpectedly independent of the ionic strength. During gel electrophoresis both BOXTO-PRO and BOXTO-MEE exhibit a faster dissociation rate than BOXTO. Still, BOXTO-PRO seems to be a good alternative as DNA probe, especially for applications in free solution where the dissociation is slower than for the corresponding intercalator TOPRO-1.     

Fluorescence in situ hybridization to interphase cell nuclei in suspension allows flow cytometric analysis of chromosome content and microscopic analysis of nuclear organization

Summary Fluorescence hybridization to interphase nuclei in liquid suspension allows quantification of chromosome-specific DNA sequences using flow cytometry and the analysis of the three-dimensional positions of these sequences in the nucleus using fluorescence microscopy. The three-dimensional structure of nuclei is substantially intact after fluorescence hybridization in suspension, permitting the study of nuclear organization by optical sectioning. Images of the distribution of probe and total DNA fluroescence within a nucleus are collected at several focal planes by quantitative fluorescence microscopy and image processing. These images can be used to reconstruct the three-dimensional organization of the target sequences in the nucleus. We demonstrate here the simultaneous localization of two human chromosomes in an interphase nucleus using two probe labeling schemes (AAF and biotin). Alternatively, dual-beam flow cytometry is used to quantify the amount of bound probe and total DNA content. We demonstrate that the intensity of probe-linked fluorescence following hybridization is proportional to the amount of target DNA over a 100-fold range in target content. This was shown using four human/hamster somatic cell hybrids carrying different numbers of human chromosomes and diploid and tetraploid human cell lines hybridized with human genomic DNA. We also show that populations of male, female, and XYY nuclei can be discriminated by measuring their fluores-cence intensity following hybridization with a Y-chromosome-specific repetitive probe. The delay in the increase in Y-specific fluorescence until the end of S-phase is consistent with the results recorded in previous studies indicating that these sequences are among the last to replicate in the genome. A chromosome-17-specific repetitive probe is used to demonstrate that target sequences as small as one megabase (Mb) can be detected using fluorescence hybridization and flow cytometry.     

Spectroscopic and molecular modeling studies of caffeine complexes with DNA intercalators.

Recent studies have demonstrated that caffeine can act as an antimutagen and inhibit the cytoxic and/or cytostatic effects of some DNA intercalating agents. It has been suggested that this inhibitory effect may be due to complexation of the DNA intercalator with caffeine. In this study we employ optical absorption, fluorescence, and molecular modeling techniques to probe specific interactions between caffeine and various DNA intercalators. Optical absorption and steady-state fluorescence data demonstrate complexation between caffeine and the planar DNA intercalator acridine orange. The association constant of this complex is determined to be 258.4 +/- 5.1 M-1. In contrast, solutions containing caffeine and the nonplanar DNA intercalator ethidium bromide show optical shifts and steady-state fluorescence spectra indicative of a weaker complex with an association constant of 84.5 +/- 3.5 M-1. Time-resolved fluorescence data indicate that complex formation between caffeine and acridine orange or ethidium bromide results in singlet-state lifetime increases consistent with the observed increase in the steady-state fluorescence yield. In addition, dynamic polarization data indicate that these complexes form with a 1:1 stoichiometry. Molecular modeling studies are also included to examine structural factors that may influence complexation.     

Design and synthesis of cell-permeable fluorescent nitrilotriacetic acid derivatives

Fluorescence labeling of the target molecules using a small molecule-based probe is superior than a method using genetically expressed green fluorescence protein (GFP) in terms of convenience in its preparation and functionalization. Fluorophore-nitrilotriacetic acid (NTA) conjugates with several ester protecting groups were synthesized and evaluated for their cell membrane permeability by fluorescence microscopy analysis. One of the derivatives, acetoxymethyl (AM)-protected NTA conjugate is hydrolyzed, resulting in intracellular accumulation, thus providing localized fluorescence intensity in cells. This modification is expected as an effective method for converting a non-cell membrane permeable NTA-BODIPY conjugates to a cell membrane permeable derivatives.     

Light-up probes: thiazole orange-conjugated peptide nucleic acid for detection of target nucleic acid in homogeneous solution

We have constructed light-up probes for nucleic acid detection. The light-up probe is a peptide nucleic acid (PNA) oligonucleotide to which the asymmetric cyanine dye thiazole orange (TO) is tethered. It combines the excellent hybridization properties of PNA and the large fluorescence enhancement of TO upon binding to DNA. When the PNA hybridizes to target DNA, the dye binds and becomes fluorescent. Free probes have low fluorescence, which may increase almost 50-fold upon hybridization to complementary nucleic acid. This makes the light-up probes particularly suitable for homogeneous hybridization assays, where separation of the bound and free probe is not necessary. We find that the fluorescence enhancement upon hybridization varies among different probes, which is mainly due to variations in free probe fluorescence. For eight probes studied the fluorescence quantum yield at 25 degrees C in the unbound state ranged from 0.0015 to 0.08 and seemed to depend mainly on the PNA sequence. The binding of the light-up probes to target DNA is highly sequence specific and a single mismatch in a 10-mer target sequence was readily identified.     

Developing a peptide-based near-infrared molecular probe for protease sensing

Recently near-infrared (NIR) molecular probes have become important reporter molecules for a number of types of in vivo biomedical imaging. A peptide-based NIR fluorescence probe consisting of a NIR fluorescence emitter (Cy5.5), a NIR fluorescence absorber (NIRQ820), and a protease selective peptide sequence was designed to sense protease activity. Using a MMP-7 model, we showed that NIRQ820 efficiently absorbs the emission energy of Cy5.5 resulting in a low initial signal. Upon reacting with its target, MMP-7, the fluorescence signal of the designed probe was increased by 7-fold with a K(cat)/K(m) of 100 000 M(-)(1) s(-)(1). The described synthetic strategy should have wide application for other NIR probe preparations.