A Dielectric-Sensitive Fluorescent DNA Probe for Monitoring Polarities on the Interior of a DNA-Binding Protein

Ultrasensitive detection of a responsive fluorescent thymidine analogue in DNA via pulse-shaped two-photon excitation

Fluorescent base analogues (FBAs) are versatile nucleic acid labels that can replace a native nucleobase, while maintaining base pairing and secondary structure. Following the recent demonstration that free FBAs can be detected at the single-molecule level, the next goal is to achieve this level of detection sensitivity in oligonucleotides. Due to the short-wavelength absorption of most FBAs, multiphoton microscopy has emerged as a promising approach to single-molecule detection. We report the multiphoton-induced fluorescence of 5-(5-(4-methoxyphenyl)thiophen-2-yl)-6-aza-uridine (MeOthaU), a polarity-sensitive fluorescent thymidine analogue, as a nucleoside, and in two single-stranded deoxyribo-oligonucleotides, with and without their complementary strands. Ensemble steady-state and time-resolved measurements in dioxane, following one-photon and two-photon excitation, reveals both strongly and weakly emissive species, assigned as rotamers, while in Tris buffer there are additional non-emissive states, which are attributed to tautomeric forms populated in aqueous environments. The two-photon (2P) brightness for MeOthaU is highest as the free nucleoside in dioxane (10 GM) and lowest as the free nucleoside in Tris buffer (0.05 GM). The species-averaged 2P brightness values in DNA are higher for the single strands (0.66 and 0.82 GM for sequence context AXA and AXT, respectively, where X is MeOthaU) than in the duplex (0.31 and 0.25 GM for AXA and AXT, respectively). Using 2P microscopy with pulse-shaped broadband excitation, we were able to detect single- and double-stranded oligos with a molecular brightness of 0.8-0.9 kHz per molecule. This allowed the detection of as few as 7 DNA molecules in the focus, making it the brightest responsive FBA in an oligonucleotide reported to date.

Environmentally sensitive fluorescent nucleoside analogues as probes for nucleic acid - protein interactions: molecular design and biosensing applications

Fluorescent nucleoside analogues (FNAs) are indispensable in studying the interactions of nucleic acids with nucleic acid-binding proteins. By replacing one of the poorly emissive natural nucleosides, FNAs enable real-time optical monitoring of the binding interactions in solutions, under physiologically relevant conditions, with high sensitivity. Besides that, FNAs are widely used to probe conformational dynamics of biomolecular complexes using time-resolved fluorescence methods. Because of that, FNAs are tools of high utility for fundamental biological research, with potential applications in molecular diagnostics and drug discovery. Here I review the structural and physical factors that can be used for the conversion of the molecular binding events into a detectable fluorescence output. Typical environmentally sensitive FNAs, their properties and applications, and future challenges in the field are discussed.

7-Hydroxy-3-methyleneisoindolin-1-one as a New ESIPT-Fluorescent Probe to Monitor Aqueous Environments

A 7-hydroxy derivative of 3-methyleneisoindolin-1-one 1 was synthesized and its properties as a new fluorophore undergoing excited-state intramolecular proton transfer (ESIPT) were investigated. In alcohols and dimethylsulfoxide, 1 exhibited dual emission at ca. 380 and 525-540 nm when excited at ca. 336 nm, which agreed well with the density functional theory (DFT) and time-dependent (TD)-DFT-calculated emission predictions of 1 and its ESIPT tautomer. In aqueous solutions at near neutral pH, 1 exhibited a broad emission band at ca. 497 nm, presumably caused by the overlap of emissions from 1 and the excited state phenolate species of 1. In binary mixtures of H₂O and EtOH, the wavelength and intensity of fluorescence maxima were dependent on the dielectric constant of the solvent, suggesting that 1 could be applied as a fluorescent probe to monitor aqueous environments.

Solvatochromic fluorene-linked nucleoside and DNA as color-changing fluorescent probes for sensing interactions

A nucleoside bearing a solvatochromic push-pull fluorene fluorophore (dCFL ) was designed and synthesized by the Sonogashira coupling of alkyne-linked fluorene 8 with 5-iodo-2'-deoxycytidine. The fluorene building block 8 and labeled nucleoside dCFL exerted bright fluorescence with significant solvatochromic effect providing emission maxima ranging from 421 to 544 nm and high quantum yields even in highly polar solvents, including water. The solvatochromism of 8 was studied by DFT and ADC(2) calculations to show that, depending on the polarity of the solvent, emission either from the planar or the twisted conformation of the excited state can occur. The nucleoside was converted to its triphosphate variant dCFLTP which was found to be a good substrate for DNA polymerases suitable for the enzymatic synthesis of oligonucleotide or DNA probes by primer extension or PCR. The fluorene-linked DNA can be used as fluorescent probes for DNA-protein (p53) or DNA-lipid interactions, exerting significant color changes visible even to the naked eye. They also appear to be suitable for time-dependent fluorescence shift studies on DNA, yielding information on DNA hydration and dynamics.

A hybridisation-dependent membrane-insertable amphiphilic DNA

We synthesized a new class of membrane-binding amphiphilic DNA consisting of hydrophilic phosphodiester-linked DNA and hydrophobic octyl phosphotriester-linked DNA. The amphiphilic DNA binds to the lipid membrane by inserting the hydrophobic region, which is facilitated by the presence of the complementary DNA strand.

Blinking triggered by the change in the solvent accessibility of a fluorescent molecule

The more a fluorescent molecule is exposed to a solvent, the faster its triplet excited state is quenched by molecular oxygen.

Selective chemical labelling of 5-formylcytosine in DNA by fluorescent dyes

Direct labelling: 5-Formylcytosine in DNA can be selectively labelled by fluorescent dyes containing an active amino group. The labelled DNA shows strong fluorescence and can be detected by polyacrylamide gel electrophoresis (PAGE) and fluorescence measurements (see scheme). This method can distinguish 5-formylcytosine from other methylation forms of cytosine in DNA.

GFP-like fluorophores as DNA labels for studying DNA-protein interactions

GFP-like 3,5-difluoro-4-hydroxybenzylideneimidazolinone (FBI) and 3,5-bis(methoxy)-4-hydroxy-benzylideneimidazolinone (MBI) labels were attached to dCTP through a propargyl linker, and the resulting labeled nucleotides (dC(MBI)TP and dC(FBI)TP) were used for a facile enzymatic synthesis of oligonucleotide or DNA probes by polymerase-catalyzed primer extension. The MBI/FBI-labeled DNA probes exerted low fluorescence that was increased 2-3.2 times upon binding of a protein. The concept was demonstrated on sequence-specific binding of p53 to dsDNA and on nonspecific binding of single strand binding protein to an oligonucleotide. The FBI label was also used for a time-resolved experiment monitoring a single-nucleotide incorporation followed by primer extension by Vent(exo-) polymerase.

Modified 6-aza uridines: highly emissive pH-sensitive fluorescent nucleosides

Optimized facile syntheses and highly desirable spectroscopic properties of two isomorphic fluorescent pyrimidines, comprising a 1,2,4-triazine motif conjugated to a thiophene (1 a) or a furan (1 b), are described. Although structurally related to their 5-modified uridine counterparts, these modified 6-aza-uridines reveal dramatically improved fluorescence properties and a remarkable sensitivity to polarity and pH changes. The thiophene derivative 1 a has an absorption maximum around 335 nm, which upon excitation yields visible emission with a polarity-sensitive maximum and fluorescence quantum yield ranging from 415 nm (Φ=0.8) to 455 nm (Φ=0.2) in dioxane and water, respectively. Nucleoside 1 a also displays susceptibility to acidity. Correlating emission intensity and solution pH yields a pK(a) value of 6.7-6.9, reasonably close to physiological pH values. The results illustrate that highly sought-after fluorescence features (brightness and responsiveness) are not necessarily the trait of large fluorophores alone, but can be observed with probes that meet stringent isomorphic design criteria.

Characterization of metal ion-nucleic acid interactions in solution

Metal ions are inextricably involved with nucleic acids due to their polyanionic nature. In order to understand the structure and function of RNAs and DNAs, one needs to have detailed pictures on the structural, thermodynamic, and kinetic properties of metal ion interactions with these biomacromolecules. In this review we first compile the physicochemical properties of metal ions found and used in combination with nucleic acids in solution. The main part then describes the various methods developed over the past decades to investigate metal ion binding by nucleic acids in solution. This includes for example hydrolytic and radical cleavage experiments, mutational approaches, as well as kinetic isotope effects. In addition, spectroscopic techniques like EPR, lanthanide(III) luminescence, IR and Raman as well as various NMR methods are summarized. Aside from gaining knowledge about the thermodynamic properties on the metal ion-nucleic acid interactions, especially NMR can be used to extract information on the kinetics of ligand exchange rates of the metal ions applied. The final section deals with the influence of anions, buffers, and the solvent permittivity on the binding equilibria between metal ions and nucleic acids. Little is known on some of these aspects, but it is clear that these three factors have a large influence on the interaction between metal ions and nucleic acids.

Developing a computational model that accurately reproduces the structural features of a dinucleoside monophosphate unit within B-DNA

The ability of a dinucleoside monophosphate to mimic the conformation of B-DNA was tested using a combination of different phosphate models (anionic, neutral, counterion), environments (gas, water), and density functionals (B3LYP, MPWB1K, M06-2X) with the 6-31G(d,p) basis set. Three sequences (5'-GX(Py)-3', where X(Py) = T, U or (Br)U) were considered, which vary in the (natural or modified) 3' pyrimidine nucleobase (X(Py)). These bases were selected due to their presence in natural DNA, structural similarity to T and/or applications in radical-initiated anti-tumour therapies. The accuracy of each of the 54 model, method and sequence combinations was judged based on the ability to reproduce key structural features of natural B-DNA, including the stacked base-base orientation and important backbone torsion angles. B3LYP yields distorted or tilted relative base-base orientations, while many computational challenges were encountered for MPWB1K. Despite wide use in computational studies of DNA, the neutral (protonated) phosphate model could not consistently predict a stacked arrangement for all sequences. In contrast, stacked base-base arrangements were obtained for all sequences with M06-2X in conjunction with both the anionic and (sodium) counterion phosphate models. However, comparison of calculated and experimental backbone conformations reveals the charge-neutralized counterion phosphate model best mimics B-DNA. Structures optimized with implicit solvent (water) are comparable to gas-phase structures, which suggests similar results should be obtained in an environment of intermediate polarity. We recommend the use of either gas-phase or water M06-2X optimizations with the counterion phosphate model to study the structure and/or reactivity of natural or modified DNA with a dinucleoside monophosphate.

Sensing peptide-oligonucleotide interactions by a two-color fluorescence label: application to the HIV-1 nucleocapsid protein

We present a new methodology for site-specific sensing of peptide–oligonucleotide (ODN) interactions using a solvatochromic fluorescent label based on 3-hydroxychromone (3HC). This label was covalently attached to the N-terminus of a peptide corresponding to the zinc finger domain of the HIV-1 nucleocapsid protein (NC). On interaction with target ODNs, the labeled peptide shows strong changes in the ratio of its two emission bands, indicating an enhanced screening of the 3HC fluorophore from the bulk water by the ODN bases. Remarkably, this two-color response depends on the ODN sequence and correlates with the 3D structure of the corresponding complexes, suggesting that the 3HC label monitors the peptide–ODN interactions site-specifically. By measuring the two-color ratio, we were also able to determine the peptide–ODN-binding parameters and distinguish multiple binding sites in ODNs, which is rather difficult using other fluorescence methods. Moreover, this method was found to be more sensitive than the commonly used steady-state fluorescence anisotropy, especially in the case of small ODNs. The described methodology could become a new universal tool for investigating peptide–ODN interactions.

Chemical approach toward efficient DNA methylation analysis

The development of a reaction for the detection of the presence/absence of one methyl group in a very long DNA strand is a chemically and biologically challenging research subject. Several newly designed chemical assays for the typing of DNA methylation are reported and discussed in this paper. A new concept of sequence-specific short-term methylation analysis, supported by a chemical basis, is the starting point for a novel methylation-typing assay, which will supersede conventional methods.

Synthesis and enzymatic incorporation of a fluorescent pyrimidine ribonucleotide

A detailed protocol for the synthesis of a fluorescent pyrimidine ribonucleoside analogue and its enzymatic incorporation into an RNA strand by transcription reactions is described. Furan-modified ribonucleoside triphosphate is synthesized in two steps with an overall yield of 33%. Incorporation of the triphosphate into an RNA oligomer occurs with nearly 225-fold amplification over the amount of the DNA template. Bacterial rRNA decoding site (known as the A-site) derived from this fluorescently modified ssRNA positively signals a binding event upon interaction with aminoglycoside antibiotics, its cognate ligands. The total time for the synthesis of ribonucleoside triphosphate is approximately 6 days, and that for the incorporation of the nucleoside triphosphate and purification of the fluorescently labeled RNA approximately 40 h.

Synthesis and site-specific incorporation of a simple fluorescent pyrimidine

We describe procedures for the synthesis of a fluorescent pyrimidine analog and its site-specific incorporation into a DNA oligomer. The 5'-protected and 3'-activated nucleoside 4 is synthesized in three steps with an overall yield of 40%. Site-specific incorporation into a DNA oligomer occurs with greater than 88% coupling efficiency. This isosteric fluorescent DNA analog can be used to monitor denaturation of DNA duplexes via fluorescence and can positively detect the presence of abasic sites in DNA duplexes. The total time for synthesis of the phosphoramidite 4 is about 75 h, whereas the total time for site-specific incorporation of nucleoside 2 into an oligonucleotide and purification of the corresponding oligonucleotide is about 114 hours.

PRODAN-conjugated DNA: synthesis and photochemical properties

A solvatochromic fluorophore, PRODAN, has been used as a microenvironment-sensitive reporter. Based on the chemistry of PRODAN, we designed and synthesized four novel fluorescent nucleosides, PDNX (X = U, C, A, and G), to which a PRODAN fluorophore was attached at pyrimidine C5 or purine C8. The fluorescent nucleosides sensitively varied the Stokes shift values depending on the orientational polarizability of the solvent. The PDNX incorporated into DNA also changed the Stokes shift values depending on the DNA structure. In particular, the excitation spectrum of the PDNX-containing duplex shifted to a longer wavelength and gave a smaller Stokes shift value when the base opposite PDNX could form a Watson-Crick base pair with PDNX. A lower energy excitation of PDNX-containing DNA resulted in a strong fluorescence emission selective to the Watson-Crick pairing base. This unique photochemical character was applicable to the efficient typing of single-nucleotide polymorphisms of genes.

Fluorescent pyrimidine ribonucleotide: synthesis, enzymatic incorporation, and utilization

Fluorescent nucleobase analogues that respond to changes in their microenvironment are valuable for studying RNA structure, dynamics, and recognition. The most commonly used fluorescent ribonucleoside is 2-aminopurine, a highly responsive purine analogue. Responsive isosteric fluorescent pyrimidine analogues are, however, rare. Appending five-membered aromatic heterocycles at the 5-position on a pyrimidine core has recently been found to provide a family of responsive fluorescent nucleoside analogues with emission in the visible range. To explore the potential utility of this chromophore for studying RNA-ligand interactions, an efficient incorporation method is necessary. Here we describe the synthesis of the furan-containing ribonucleoside and its triphosphate, as well as their basic photophysical characteristics. We demonstrate that T7 RNA polymerase accepts this fluorescent ribonucleoside triphosphate as a substrate in in vitro transcription reactions and very efficiently incorporates it into RNA oligonucleotides, generating fluorescent constructs. Furthermore, we utilize this triphosphate for the enzymatic preparation of a fluorescent bacterial A-site, an RNA construct of potential therapeutic utility. We show that the binding of this RNA target to aminoglycoside antibiotics, its cognate ligands, can be effectively monitored by fluorescence spectroscopy. These observations are significant since isosteric emissive U derivatives are scarce and the trivial synthesis and effective enzymatic incorporation of the furan-containing U triphosphate make it accessible to the biophysical community.

Methylcytosine-selective fluorescence quenching by osmium complexation

We report on the control of the emission from a fluorophore fixed on DNA using the methylcytosine-selective addition of an osmium-bipyridine complex. We have synthesized DNA modified by a microenvironment-sensitive fluorophore, 2-dimethylamino-6-acyl-naphthalene. The emission from the fluorophore tethered to a probe DNA was effectively quenched by a methylcytosine glycol-osmium-bipyridine triad, which was located in the immediate neighborhood of the fluorophore. The discrimination of the cytosine methylation status at a methylation hot spot in the p53 gene was also executed using a well-designed fluorescent DNA probe.

Nile Red Nucleoside: Design of a Solvatofluorochromic Nucleoside as an Indicator of Micropolarity around DNA

The fluorophore, Nile Red, effectively works as a polarity-sensitive fluorescence probe. We have designed a new nucleoside modified by Nile Red for examining the change in the polarity of the microenvironment surrounding DNA. We synthesized a Nile Red nucleoside (1), formed by replacing nucleobases with Nile Red, through the coupling of a 2-hydroxylated Nile Red derivative and 1,2-dideoxyglycan. This nucleoside showed a high solvatofluorochromicity. The fluorescence of 1 incorporated into DNA was greatly shifted to shorter wavelength by the addition of beta-cyclodextrin. The photophysical function of the Nile Red nucleoside will be a good optical indicator for monitoring the change in the micropolarity properties at a specific site on target sequences with interaction between DNA and DNA-binding molecules.