Forced Intercalation Probes (FIT Probes): Thiazole Orange as a Fluorescent Base in Peptide Nucleic Acids for Homogeneous Single‐Nucleotide‐Polymorphism Detection

Self Cite

Double‐stranded DNA offers multiple binding sites to DNA stains. Measurements of noncovalently bound dye–nucleic acid complexes are, necessarily, measurements of an ensemble of chromophores. Thus, it is difficult to assign fluorescence properties to base‐pair‐specific binding modes of cyanine dyes or, vice versa, to obtain information about the local environment of cyanines in nucleic acids by using optical spectroscopy. The feasibility to stain DNA and simultaneously probe local perturbations by optical spectroscopy would be a valuable asset to nucleic acid research. So‐called FIT probes (forced intercalation probes) were used to pinpoint the location of the DNA stain thiazole orange (TO) in PNA⋅DNA duplexes. A detailed analysis of the base‐pair dependence of optical properties is provided and enforced binding of TO is compared with “classical” binding of free TO‐PRO1. UV‐visible absorbance, circular dichroism (CD) and fluorescence spectroscopy, and melting‐curve analyses confirmed site‐specific TO intercalation. Thiazole orange exhibited base‐specific responses that are not observed in noncovalent dye–nucleic acid complexes, such as an extraordinary dependence of the TO extinction coefficient (±60 % variation of the averaged εmax of 57 000 M−1 cm−1) on nearest‐neighbor base pairs. TO signals hybridization, as shown by increases in the steady‐state fluorescence emission. Studies of TO fluorescence lifetimes in FIT–PNA and in DNA⋅DNA and PNA⋅DNA complexes highlighted four different fluorescence‐decay processes that may be closed or opened in response to matched or single‐mismatched hybridization. A very fast decay process (0.04–0.07 ns) and a slow decay process (2.33–3.95 ns) provide reliable monitors of hybridization, and the opening of a fast decay channel (0.22–0.48 ns) that resulted in an attenuation of the fluorescence emission is observed upon the formation of mismatched base pairs.

Section: Introductionmentioning

confidence: 99%

Exploring Base‐Pair‐Specific Optical Properties of the DNA Stain Thiazole Orange

Jarikote

Krebs

Tannert

et al. 2006

Self Cite

“…[11,12] Instead of using interactions between two extrinsic probes, interactions of one fluorophore with DNA bases can be used for specific detection of nucleic acid sequences. [13,14] Besides the use of fluorescein, [15,16] very recently fluorene has also been incorporated into the loop structure of a hairpin architecture. [17] A single base mismatch was detected by de-quenching upon hybridization with the fully matched target and quenching upon hybridization with a target containing a single base mutation.…”

Section: Introductionmentioning

confidence: 99%

Twin Probes as a Novel Tool for the Detection of Single‐Nucleotide Polymorphisms

Ergen

Weber

Jacob

et al. 2006

Single‐nucleotide polymorphisms (SNPs) are the most common form of DNA sequence variation. There is a strong interest from both academy and industry to develop rapid, sensitive and cost effective methods for SNP detection. Here we report a novel structural concept for DNA detection based on fluorescence dequenching upon hybridization. The so‐called “twin probe” consists of a central fluorene derivative as fluorophore to which two identical oligonucleotides are covalently attached. This probe architecture is applied in homogeneous hybridization assays with subsequent fluorescence spectroscopic analysis. The bioorganic hybrid structure is well suited for sequence specific DNA detection and even SNPs are identified with high efficiency. Additionally, the photophysical properties of the twin probe were investigated. The covalent attachment of two single stranded oligonucleotides leads to strong quenching of the central fluorescence dye induced by the nucleobases. The twin probe is characterized by supramolecular aggregate formation accompanied by red‐shifted emission and broad fluorescence spectra.

“…[29][30][31] YO and TO have also been covalently linked to oligonucleotides and inserted into peptide nucleic acids constructs, which become fluorescent upon hybridisation of the light-up probe to a specific complementary strand. [32][33][34][35][36][37][38] The origin of the very high contrast in emission between the free and the bound form of the dyes has long been thought to be due to an ultrafast decay of the excited state of the free form through a large-amplitude torsional motion around the monomethine bond connecting the benzoxazole, benzothiazole and quinoline moieties, respectively. [39,40] This isomerisation mechanism is blocked upon intercalation of the dyes into DNA and, as a consequence, they light-up by three orders of magnitude.…”

mentioning

confidence: 99%

Structure–Fluorescence Contrast Relationship in Cyanine DNA Intercalators: Toward Rational Dye Design

Fürstenberg

Deligeorgiev

Gadjev

et al. 2007

The fluorescence enhancement mechanisms of a series of DNA stains of the oxazole yellow (YO) family have been investigated in detail using steady‐state and ultrafast time‐resolved fluorescence spectroscopy. The strong increase in the fluorescence quantum yield of these dyes upon DNA binding is shown to originate from the inhibition of two distinct processes: 1) isomerisation through large‐amplitude motion that non‐radiatively deactivates the excited state within a few picoseconds and 2) formation of weakly emitting H‐dimers. As the H‐dimers are not totally non‐fluorescent, their formation is less efficient than isomerisation as a fluorescent contrast mechanism. The propensity of the dyes to form H‐dimers and thus to reduce their fluorescence contrast upon DNA binding is shown to depend on several of their structural parameters, such as their monomeric (YO) or homodimeric (YOYO) nature, their substitution and their electric charge. Moreover, these parameters also have a substantial influence on the affinity of the dyes for DNA and on the ensuing sensitivity for DNA detection. The results give new insight into the development and optimisation of fluorescent DNA probes with the highest contrast.