Fluorescent Probes for G‐Quadruplex Structures

Mounting evidence supports the presence of biologically relevant G‐quadruplexes in single‐cell organisms, but the existence of endogenous G‐quadruplex structures in mammalian cells remains highly controversial. This is due, in part, to the common misconception that DNA and RNA molecules are passive information carriers with relatively little structural or functional complexity. For those working in the field, however, the lack of available tools for characterizing DNA structures in vivo remains a major limitation to addressing fundamental questions about structure–function relationships of nucleic acids. In this review, we present progress towards the direct detection of G‐quadruplex structures by using small molecules and modified oligonucleotides as fluorescent probes. While most development has focused on cell‐permeable probes that selectively bind to G‐quadruplex structures with high affinity, these same probes can induce G‐quadruplex folding, thereby making the native conformation of the DNA or RNA molecule (i.e., in the absence of probe) uncertain. For this reason, modified oligonucleotides and fluorescent base analogues that serve as “internal” fluorescent probes are presented as an orthogonal means for detecting conformational changes, without necessarily perturbing the equilibria between G‐quadruplex, single‐stranded, and duplex DNA. The major challenges and motivation for the development of fluorescent probes for G‐quadruplex structures are presented, along with a summary of the key photophysical, biophysical, and biological properties of reported examples.     

Readily Accessible Fluorescent Probes for Sensitive Biological Imaging of Hydrogen Peroxide

Hydrogen peroxide is a major component of oxygen metabolism in biological systems that, when present in high concentrations, can lead to oxidative stress in cells. Noninvasive molecular imaging of H₂O₂ using fluorogenic systems represents an effective way to detect and measure the accumulation of this metabolite. Herein, we detail the development of robust H₂O₂‐sensitive fluorescent probes using a boronic ester trigger appended to the fluorophore through a benzyl ether linkage. A major advantage of the probes presented here is their synthetic accessibility, with only one step needed to generate the probes on the gram scale. The sensitivity of the probes was evaluated in simulated physiological conditions, showing micromolar sensitivity to H₂O₂. The probes were tested in biological model systems, demonstrating effective imaging of unstimulated, endogenous H₂O₂ levels in RAW 264.7 cells and murine brain tissue.     

Multiparameter imaging for the analysis of intracellular signaling

In biological experimentation and especially in drug discovery there is a trend towards more complex test systems. Cell-based assays are replacing conventional binding or enzyme assays more and more. This development is strongly driven by novel fluorescent probes that give insight into cellular processes. Target proteins are studied in their natural environment; this gives much more realistic test results, especially with respect to enzyme location and kinetics. However, in the complex environment of cells, many parameters contribute to the performance of the protein of interest. Therefore, it would be desirable to monitor simultaneously as many of the relevant cellular processes as possible. Here, we discuss the possibilities and limitations provided by multiparameter monitoring of cellular events with fluorescent probes. Some novel examples of the use of fluorescent probes and multiparameter imaging are shown.     

Design and Expeditious Synthesis of Quinoline-Pyrene-Based Ratiometric Fluorescent Probes for Targeting Lysosomal pH

Intracellular pH plays a significant role in many pathological and physiological processes. A series of quinoline-pyrene probes were synthesized in one-step fashion through an oxonium-ion-triggered alkyne carboamination sequence involving C−C, C−O and C−N bond formation for intracellular pH sensing. The quinoline-pyrenes showed significant red shifts at low pH. Fluorescence lifetime decay measurements of the probes showed decreases in lifetime at pH 4. The probes showed excellent selectivity in the presence of various potential interfering agents such as amino acids and cations/anions. Furthermore, the probes were found to show completely reversible emission behaviour in the window between pH 4 and 7. A morpholine-substituted quinoline-pyrene probe efficiently stained lysosomes with high Pearson correlation coefficients (0.86) with Lysotracker Deep Red DND-99 as a reference. A co-localization study of the probe with Lysotracker DND-99 showed selective intracellular targeting and a shift in fluorescence emission due to acidic lysosomal pH.     

Position‐Specific Incorporation of Fluorescent Non‐natural Amino Acids into Maltose‐Binding Protein for Detection of Ligand Binding by FRET and Fluorescence Quenching

FRETting about MBP : Position‐specific incorporation of fluorescent groups is a useful method for analysis of the functions and structures of proteins. Here we demonstrate that position‐specific incorporation of fluorescent non‐natural amino acids in response to expanded codons enables us to detect ligand‐binding activity of maltose‐binding protein (MBP) through fluorescence resonance energy transfer (FRET) and ligand‐dependent fluorescence quenching.

     

Development of Ratiometric Fluorescent Probes for Phosphatases by Using a pKa Switching Mechanism

A novel design strategy for fluorescent probes based on a pK_a switching mechanism was developed. Using this strategy, we developed ratiometric probes for the detection of acid phosphatase activity.

     

Polyamide Fluorescent Probes for Visualization of Repeated DNA Sequences in Living Cells

DNA imaging in living cells usually requires transgenic approaches that modify the genome. Synthetic pyrrole‐imidazole polyamides that bind specifically to the minor groove of double‐stranded DNA (dsDNA) represent an attractive approach for in‐cell imaging that does not necessitate changes to the genome. Nine hairpin polyamides that target mouse major satellite DNA were synthesized. Their interactions with synthetic target dsDNA fragments were studied by thermal denaturation, gel‐shift electrophoresis, circular dichroism, and fluorescence spectroscopy. The polyamides had different affinities for the target DNA, and fluorescent labeling of the polyamides affected their affinity for their targets. We validated the specificity of the probes in fixed cells and provide evidence that two of the probes detect target sequences in mouse living cell lines. This study demonstrates for the first time that synthetic compounds can be used for the visualization of the nuclear substructures formed by repeated DNA sequences in living cells.     

Ultramild Protein‐Mediated Click Chemistry Creates Efficient Oligonucleotide Probes for Targeting and Detecting Nucleic Acids

Functionalized synthetic oligonucleotides are finding growing applications in research, clinical studies, and therapy. However, it is not easy to prepare them in a biocompatible and highly efficient manner. We report a new strategy to synthesize oligonucleotides with promising nucleic acid targeting and detection properties. We focus in particular on the pH sensitivity of these new probes and their high target specificity. For the first time, human copper(I)‐binding chaperon Cox17 was applied to effectively catalyze click labeling of oligonucleotides. This was performed under ultramild conditions with fluorophore, peptide, and carbohydrate azide derivatives. In thermal denaturation studies, the modified probes showed specific binding to complementary DNA and RNA targets. Finally, we demonstrated the pH sensitivity of the new rhodamine‐based fluorescent probes in vitro and rationalize our results by electronic structure calculations.     

Probing Human Telomeric DNA and RNA Topology and Ligand Binding in a Cellular Model by Using Responsive Fluorescent Nucleoside Probes

The development of biophysical systems that enable an understanding of the structure and ligand‐binding properties of G‐quadruplex (GQ)‐forming nucleic acid sequences in cells or models that mimic the cellular environment would be highly beneficial in advancing GQ‐directed therapeutic strategies. Herein, the establishment of a biophysical platform to investigate the structure and recognition properties of human telomeric (H‐Telo) DNA and RNA repeats in a cell‐like confined environment by using conformation‐sensitive fluorescent nucleoside probes and a widely used cellular model, bis(2‐ethylhexyl) sodium sulfosuccinate reverse micelles (RMs), is described. The 2′‐deoxy and ribonucleoside probes, composed of a 5‐benzofuran uracil base analogue, faithfully report the aqueous micellar core through changes in their fluorescence properties. The nucleoside probes incorporated into different loops of H‐Telo DNA and RNA oligonucleotide repeats are minimally perturbing and photophysically signal the formation of respective GQ structures in both aqueous buffer and RMs. Furthermore, these sensors enable a direct comparison of the binding affinity of a ligand to H‐Telo DNA and RNA GQ structures in the bulk and confined environment of RMs. These results demonstrate that this combination of a GQ nucleoside probe and easy‐to‐handle RMs could provide new opportunities to study and devise screening‐compatible assays in a cell‐like environment to discover GQ binders of clinical potential.     

Mechanism toward Turn-on of Polysaccharide-Porphyrin Complexes for Fluorescence Probes and Photosensitizers in Photodynamic Therapy in Living Cells

β-(1,3-1,6)-D-Glucan, λ-carrageenan, tamarind gum, and pullulan can dissolve various porphyrin derivatives via the formation of complexes in water using a high-speed vibration milling method. The aqueous solutions of the resulting complexes exhibit long-term stability. Despite the adverse effects of the self-quenching process, notable fluorescence and improved photodynamic activity of the polysaccharide-complexed porphyrin derivatives were observed in the presence of liposomes, micelles, cyclodextrins, and HeLa cells. It was noted that the type of porphyrins was more important than the type of polysaccharides present in the complex. Porphyrin self-aggregates were monodispersed in the lipid membranes of the liposomes and lysosomes. The polysaccharide-complexed porphyrin derivatives showed increased photodynamic activity toward HeLa cells under photoirradiation between 610 and 740 nm.     

2′‐Bispyrene‐Modified 2′‐O‐Methyl RNA Probes as Useful Tools for the Detection of RNA: Synthesis,Fluorescent Properties,and Duplex Stability

The synthesis and properties two series of new 2′‐O‐methyl RNA probes, each containing a single insertion of a 2′‐bispyrenylmethylphosphorodiamidate derivative of a nucleotide (U, C, A, and G), are described. As demonstrated by UV melting studies, the probes form stable complexes with model RNAs and DNAs. Significant increases (up to 21‐fold) in pyrene excimer fluorescence intensity were observed upon binding of most of the probes with complementary RNAs, but not with DNAs. The fluorescence spectra are independent of the nature of the modified nucleotides. The nucleotides on the 5′‐side of the modified nucleotide have no effect on the fluorescence spectra, whereas the natures of the two nucleotides on the 3′‐side are important: CC, CG, and UC dinucleotide units on the 3′‐side of the modified nucleotide provide the maximum increases in excimer fluorescence intensity. This study suggests that these 2′‐bispyrene‐labeled 2′‐O‐methyl RNA probes might be useful tools for detection of RNAs.     

Imaging of KCa3.1 Channels in Tumor Cells with PET and Small-Molecule Fluorescent Probes

The Ca²⁺ activated K⁺ channel K_Ca3.1 is overexpressed in several human tumor cell lines, e. g. clear cell renal carcinoma, prostate cancer, non-small cell lung cancer. Highly aggressive cancer cells use this ion channel for key processes of the metastatic cascade such as migration, extravasation and invasion. Therefore, small molecules, which are able to image this K_Ca3.1 channel in vitro and in vivo represent valuable diagnostic and prognostic tool compounds. The [¹⁸F]fluoroethyltriazolyl substituted senicapoc was used as positron emission tomography (PET) tracer and showed promising properties for imaging of K_Ca3.1 channels in lung adenocarcinoma cells in mice. The novel senicapoc BODIPY conjugates with two F-atoms ( 9 a ) and with a F-atom and a methoxy moiety ( 9 b ) at the B-atom led to the characteristic punctate staining pattern resulting from labeling of single K_Ca3.1 channels in A549-3R cells. This punctate pattern was completely removed by preincubation with an excess of senicapoc confirming the high specificity of K_Ca3.1 labeling. Due to the methoxy moiety at the B-atom and the additional oxyethylene unit in the spacer, 9 b exhibits higher polarity, which improves solubility and handling without reduction of fluorescence quantum yield. Docking studies using a cryo-electron microscopy (EM) structure of the K_Ca3.1 channel confirmed the interaction of 9 a and 9 b with a binding pocket in the channel pore.     

Endo‐β‐Glucosidase Tag Allows Dual Detection of Fusion Proteins by Fluorescent Mechanism‐Based Probes and Activity Measurement

β‐Glucoside‐configured cyclophellitols are activity‐based probes (ABPs) that allow sensitive detection of β‐glucosidases. Their applicability to detect proteins fused with β‐glucosidase was investigated in the cellular context. The tag was Rhodococcus sp. M‐777 endoglycoceramidase II (EGCaseII), based on its lack of glycans and ability to hydrolyze fluorogenic 4‐methylumbelliferyl β‐d ‐lactoside (an activity absent in mammalian cells). Specific dual detection of fusion proteins was possible in vitro and in situ by using fluorescent ABPs and a fluorogenic substrate. Pre‐blocking with conduritol β‐epoxide (a poor inhibitor of EGCaseII) eliminated ABP labeling of endogenous β‐glucosidases. ABPs equipped with biotin allowed convenient purification of the fusion proteins. Diversification of ABPs (distinct fluorophores, fluorogenic high‐resolution detection moieties) should assist further research in living cells and organisms.