In-Stem Molecular Beacon Containing a Pseudo Base Pair of Threoninol Nucleotides for the Removal of Background Emission

Peptide-Based Probes with an Artificial Anion-Binding Motif for Direct Fluorescence "Switch-On" Detection of Nucleic Acid in Cells

This work reports two new peptide-based fluorescence probes (1 and 2) for the detection of ds-DNA at physiological pH. Probes 1 and 2 contain a fluorophore, either amino-naphthalimide or diethyl-aminocoumarin, respectively, and two identical peptide arms each equipped with a guanidiniocarbonylpyrrole (GCP) anion-binding motif. These probes show "switch-on" fluorescence response upon binding to ds-DNA, whereby they can differentiate between various types of polynucleotides. For instance, they exhibit more pronounced fluorescence response for AT-rich polynucleotides than GC-rich polynucleotides, and both give only negligible response to ds-RNA. The fluorimetric response of 1 is proportional to the AT-basepair content in DNA, whereas the fluorescence of 2 is sensitive to the secondary structure of the polynucleotide. Fluorescence experiments, thermal melting experiments and circular dichroism studies suggest that 1 interacts with ds-DNA in a combined intercalation and minor groove binding, whereas 2 interacts mainly with the outer surface of DNA/RNA. As 1 and 2 have a very low cytotoxicity, 1 can be applied for the imaging of nuclear DNA in cells.

The role of duplex stability for wavelength-shifting fluorescent DNA probes: energy transfer vs. exciton interactions in DNA "traffic lights"

Exciton interactions between thiazole orange and thiazole red as nucleotide substitutes in DNA hairpins interfere with efficient energy transfer and fluorescence color change as readout. This interference can be tuned by two structural parameters that control the hairpin duplex stability.

Rational design for cooperative recognition of specific nucleobases using β-cyclodextrin-modified DNAs and fluorescent ligands on DNA and RNA scaffolds

We propose a binary fluorimetric method for DNA and RNA analysis by the combined use of two probes rationally designed to work cooperatively. One probe is an oligonucleotide (ODN) conjugate bearing a β-cyclodextrin (β-CyD). The other probe is a small reporter ligand, which comprises linked molecules of a nucleobase-specific heterocycle and an environment-sensitive fluorophore. The heterocycle of the reporter ligand recognizes a single nucleobase displayed in a gap on the target labeled with the conjugate and, at the same time, the fluorophore moiety forms a luminous inclusion complex with nearby β-CyD. Three reporter ligands, MNDS (naphthyridine-dansyl linked ligand), MNDB (naphthyridine-DBD), and DPDB (pyridine-DBD), were used for DNA and RNA probing with 3'-end or 5'-end modified β-CyD-ODN conjugates. For the DNA target, the β-CyD tethered to the 3'-end of the ODN facing into the gap interacted with the fluorophore sticking out into the major groove of the gap site (MNDS and DPDB). Meanwhile the β-CyD on the 5'-end of the ODN interacted with the fluorophore in the minor groove (MNDB and DPDB). The results obtained by this study could be a guideline for the design of binary DNA/RNA probe systems based on controlling the proximity of functional molecules.

Reversed assembly of dyes in an RNA duplex compared with those in DNA

We prepared reversed dye clusters by hybridizing two RNA oligomers, each of which tethered dyes (Methyl Red, 4'-methylthioazobenzene, and thiazole orange) on D-threoninols (threoninol nucleotides) at the center of their strands. NMR spectroscopic analyses revealed that two dyes from each strand were axially stacked in an antiparallel manner to each other in the duplex, and were located adjacent to the 3'-side of a natural nucleobase. Interestingly, this positional relationship of the dyes was completely the opposite of that assembled in DNA that we reported previously: dyes in DNA were located adjacent to the 5'-side of a natural nucleobase. This observation was also consistent with the circular dichroism of dimerized dyes in which the Cotton effect of the dyes (i.e., the winding properties of two dyes) was inverted in RNA relative to that in DNA. Further spectroscopic analyses revealed that clustering of the dyes on RNA duplexes induced distinct hypsochromicity and narrowing of the band, thus demonstrating that the dyes were axially stacked (i.e., H-aggregates) even on an A-type helix. On the basis of these results, we also prepared heterodimers of a fluorophore (thiazole orange) and quencher (Methyl Red) in an RNA duplex. Fluorescence from thiazole orange was found to be strongly quenched by Methyl Red due to the excitonic interaction, so that the ratio of fluorescent intensities of the RNA-thiazole orange conjugate with and without its complementary strand carrying a quencher became as high as 27. We believe that these RNA-dye conjugates are potentially useful probes for real-time monitoring of RNA interference (RNAi) mechanisms.

"DNA traffic lights": concept of wavelength-shifting DNA probes and application in an aptasensor

Add it and see it: The concept of "DNA traffic lights" for wavelength-shifting DNA probes has a great potential in the application of biosensors, for example, in DNA aptamers. A visual color change in the DNA aptasensor fluorescence from green to red occurs after specific target binding.

A two-color, self-controlled molecular beacon

Control yourself! A two-color molecular beacon with non-nucleosidic chromophores in a triplex stem is presented. Pyrene and PDI fluorophores act as mutual quenchers by formation of a donor-acceptor complex in the closed form. Hybridization with the target results in two independent fluorescence signals. The two-color read-out provides a "self-control" feature, which helps to eliminate false positive signals in imaging and screening applications.