An Aggregating Amphiphilic Squaraine: A Light‐up Probe That Discriminates Parallel G‐Quadruplexes

G‐quadruplexes (G4s) are peculiar DNA or RNA tertiary structures that are involved in the regulation of many biological events within mammalian cells, bacteria, and viruses. Although their role as versatile therapeutic targets has been emphasized for 35 years, G4 selectivity over ubiquitous double‐stranded DNA/RNA, as well as G4 differentiation by small molecules, still remains challenging. Here, a new amphiphilic dicyanovinyl‐substituted squaraine, SQgl , is reported to act as an NIR fluorescent light‐up probe discriminating an extensive panel of parallel G4s while it is non‐fluorescent in the aggregated state. The squaraine can form an unconventional sandwich π‐complex binding two quadruplexes, which leads to a strongly fluorescent (Φ _F=0.61) supramolecular architecture. SQgl is highly selective against non‐quadruplex and non‐parallel G4 sequences without altering their topology, as desired for applications in selective in vivo high‐resolution imaging and theranostics.     

Dual Binding of an Antibody and a Small Molecule Increases the Stability of TERRA G‐Quadruplex

In investigating the binding interactions between the human telomeric RNA (TERRA) G‐quadruplex (GQ) and its ligands, it was found that the small molecule carboxypyridostatin (cPDS) and the GQ‐selective antibody BG4 simultaneously bind the TERRA GQ. We previously showed that the overall binding affinity of BG4 for RNA GQs is not significantly affected in the presence of cPDS. However, single‐molecule mechanical unfolding experiments revealed a population (48 %) with substantially increased mechanical and thermodynamic stability. Force‐jump kinetic investigations suggested competitive binding of cPDS and BG4 to the TERRA GQ. Following this, the two bound ligands slowly rearrange, thereby leading to the minor population with increased stability. Given the relevance of G‐quadruplexes in the regulation of biological processes, we anticipate that the unprecedented conformational rearrangement observed in the TERRA‐GQ–ligand complex may inspire new strategies for the selective stabilization of G‐quadruplexes in cells.     

Direct and Single‐Molecule Visualization of the Solution‐State Structures of G‐Hairpin and G‐Triplex Intermediates

We present the direct and single‐molecule visualization of the in‐pathway intermediates of the G‐quadruplex folding that have been inaccessible by any experimental method employed to date. Using DNA origami as a novel tool for the structural control and high‐speed atomic force microscopy (HS‐AFM) for direct visualization, we captured images of the unprecedented solution‐state structures of a tetramolecular antiparallel and (3+1)‐type G‐quadruplex intermediates, such as G‐hairpin and G‐triplex, with nanometer precision. No such structural information was reported previously with any direct or indirect technique, solution or solid‐state, single‐molecule or bulk studies, and at any resolution. Based on our results, we proposed a folding mechanism of these G‐quadruplexes.     

Energetic Basis of AGCGA‐Rich DNA Folding into a Tetrahelical Structure

It was recently discovered that, besides well‐known G‐quadruplexes and i‐motifs, DNA may adopt another type of noncanonical structure called AGCGA‐quadruplexes. Here, the folding of the VK2 fragment from the regulatory region of the PLEKHG3 gene is studied and, for the first time, the energetic contributions that stabilize this unique fold are described. Similarly to the B‐DNA, it is stabilized by hydrophobic desolvation and, in contrast to G‐quadruplexes, also by specific binding of water molecules. Compared to B‐DNA, VK2 folding is enthalpically less favorable due to poorer base‐stacking interactions, resulting in substantial conformational flexibility. This entropically favorable conformational “breathing” stabilizes the AGCGA‐quadruplexes. In conclusion, AGCGA‐quadruplexes have a distinguishing thermodynamic fingerprint and the corresponding driving forces enabling their folding are consistent with the observed structural features.     

Orienting Tetramolecular G‐Quadruplex Formation: The Quest for the Elusive RNA Antiparallel Quadruplex

DNA and RNA G‐quadruplexes (G4) are unusual nucleic acid structures involved in a number of key biological processes. RNA G‐quadruplexes are less studied although recent evidence demonstrates that they are biologically relevant. Compared to DNA quadruplexes, RNA G4 are generally more stable and less polymorphic. Duplexes and quadruplexes may be combined to obtain pure tetrameric species. Here, we investigated whether classical antiparallel duplexes can drive the formation of antiparallel tetramolecular quadruplexes. This concept was first successfully applied to DNA G4. In contrast, RNA G4 were found to be much more unwilling to adopt the forced antiparallel orientation, highlighting that the reason RNA adopts a different structure must not be sought in the loops but in the G‐stem structure itself. RNA antiparallel G4 formation is likely to be restricted to a very small set of peculiar sequences, in which other structural features overcome the formidable intrinsic barrier preventing its formation.     

Quantitative Detection of G‐Quadruplex DNA in Live Cells Based on Photon Counts and Complex Structure Discrimination

G‐quadruplex DNA show structural polymorphism, leading to challenges in the use of selective recognition probes for the accurate detection of G‐quadruplexes in vivo. Herein, we present a tripodal cationic fluorescent probe, NBTE , which showed distinguishable fluorescence lifetime responses between G‐quadruplexes and other DNA topologies, and fluorescence quantum yield (Φ_f) enhancement upon G‐quadruplex binding. We determined two NBTE ‐G‐quadruplex complex structures with high Φ_f values by NMR spectroscopy. The structures indicated NBTE interacted with G‐quadruplexes using three arms through π–π stacking, differing from that with duplex DNA using two arms, which rationalized the higher Φ_f values and lifetime response of NBTE upon G‐quadruplex binding. Based on photon counts of FLIM, we detected the percentage of G‐quadruplex DNA in live cells with NBTE and found G‐quadruplex DNA content in cancer cells is 4‐fold that in normal cells, suggesting the potential applications of this probe in cancer cell detection.     

Non‐B DNA Structures Show Diverse Conformations and Complex Transition Kinetics Comparable to RNA or Proteins—A Perspective from Mechanical Unfolding and Refolding Experiments

With the firm demonstration of the in vivo presence and biological functions of many non‐B DNA structures, it is of great significance to understand their physiological roles from the perspective of structural conformation, stability, and transition kinetics. Although relatively simple in primary sequences compared to proteins, non‐B DNA species show rather versatile conformations and dynamic transitions. As the most‐studied non‐B DNA species, the G‐quadruplex displays a myriad of conformations that can interconvert between each other in different solutions. These features impose challenges for ensemble‐average techniques, such as X‐ray crystallography, NMR spectroscopy, and circular dichroism (CD), but leave room for single‐molecular approaches to illustrate the structure, stability, and transition kinetics of individual non‐B DNA species in a solution mixture. Deconvolution of the mixture can be further facilitated by statistical data treatment, such as iPoDNano (i ntegrated po pulation d econvolution with nano meter resolution), which resolves populations with subnanometer size differences. This Personal Account summarizes current mechanical unfolding and refolding methods to interrogate single non‐B DNA species, with an emphasis on DNA G‐quadruplexes and i‐motifs. These single‐molecule studies start to demonstrate that structures and transitions in non‐B DNA species can approach the complexity of those in RNA or proteins, which provides solid justification for the biological functions carried out by non‐B DNA species.     

Involvement of Long‐Lived Intermediate States in the Complex Folding Pathway of the Human Telomeric G‐Quadruplex

The energy landscapes of human telomeric G‐quadruplexes are complex, and their folding pathways have remained largely unexplored. By using real‐time NMR spectroscopy, we investigated the K⁺‐induced folding of the human telomeric DNA sequence 5′‐TTGGG(TTAGGG)₃A‐3′. Three long‐lived states were detected during folding: a major conformation (hybrid‐1), a previously structurally uncharacterized minor conformation (hybrid‐2), and a partially unfolded state. The minor hybrid‐2 conformation is formed faster than the more stable hybrid‐1 conformation. Equilibration of the two states is slow and proceeds via a partially unfolded intermediate state, which can be described as an ensemble of hairpin‐like structures.     

In Situ Spatial Complementation of Aptamer‐Mediated Recognition Enables Live‐Cell Imaging of Native RNA Transcripts in Real Time

Direct cellular imaging of the localization and dynamics of biomolecules helps to understand their function and reveals novel mechanisms at the single‐cell resolution. In contrast to routine fluorescent‐protein‐based protein imaging, technology for RNA imaging remains less well explored because of the lack of enabling technology. Herein, we report the development of an aptamer‐initiated fluorescence complementation (AiFC) method for RNA imaging by engineering a green fluorescence protein (GFP)‐mimicking turn‐on RNA aptamer, Broccoli, into two split fragments that could tandemly bind to target mRNA. When genetically encoded in cells, endogenous mRNA molecules recruited Split‐Broccoli and brought the two fragments into spatial proximity, which formed a fluorophore‐binding site in situ and turned on fluorescence. Significantly, we demonstrated the use of AiFC for high‐contrast and real‐time imaging of endogenous RNA molecules in living mammalian cells. We envision wide application and practical utility of this enabling technology to in vivo single‐cell visualization and mechanistic analysis of macromolecular interactions.     

Targeting RNA G‐Quadruplex in SARS‐CoV‐2: A Promising Therapeutic Target for COVID‐19?

The COVID‐19 pandemic caused by SARS‐CoV‐2 has become a global threat. Understanding the underlying mechanisms and developing innovative treatments are extremely urgent. G‐quadruplexes (G4s) are important noncanonical nucleic acid structures with distinct biofunctions. Four putative G4‐forming sequences (PQSs) in the SARS‐CoV‐2 genome were studied. One of them (RG‐1), which locates in the coding sequence region of SARS‐CoV‐2 nucleocapsid phosphoprotein (N), has been verified to form a stable RNA G4 structure in live cells. G4‐specific compounds, such as PDP (pyridostatin derivative), can stabilize RG‐1 G4 and significantly reduce the protein levels of SARS‐CoV‐2 N by inhibiting its translation both in vitro and in vivo. This result is the first evidence that PQSs in SARS‐CoV‐2 can form G4 structures in live cells, and that their biofunctions can be regulated by a G4‐specific stabilizer. This finding will provide new insights into developing novel antiviral drugs against COVID‐19.     

Fluorophore‐Promoted RNA Folding and Photostability Enables Imaging of Single Broccoli‐Tagged mRNAs in Live Mammalian Cells

Spinach and Broccoli are fluorogenic RNA aptamers that bind DFHBI, a mimic of the chromophore in green fluorescent protein, and activate its fluorescence. Spinach/Broccoli‐DFHBI complexes exhibit high fluorescence in vitro, but they exhibit lower fluorescence in mammalian cells. Here, computational screening was used to identify BI, a DFHBI derivative that binds Broccoli with higher affinity and leads to markedly higher fluorescence in cells compared to previous ligands. BI prevents thermal unfolding of Broccoli at 37 °C, leading to more folded Broccoli and thus more fluorescent Broccoli‐BI complexes in cells. Broccoli‐BI complexes are more photostable owing to impaired photoisomerization and rapid unbinding of photoisomerized cis‐BI. These properties enable single mRNA containing 24 Broccoli aptamers to be imaged in live mammalian cells treated with BI. Small molecule ligands can thus promote RNA folding in cells, and thus allow single mRNA imaging with fluorogenic aptamers.     

An Aggregating Amphiphilic Squaraine: A Light-up Probe That Discriminates Parallel G-Quadruplexes

G-quadruplexes (G4s) are peculiar DNA or RNA tertiary structures that are involved in the regulation of many biological events within mammalian cells, bacteria, and viruses. Although their role as versatile therapeutic targets has been emphasized for 35 years, G4 selectivity over ubiquitous double-stranded DNA/RNA, as well as G4 differentiation by small molecules, still remains challenging. Here, a new amphiphilic dicyanovinyl-substituted squaraine, SQgl , is reported to act as an NIR fluorescent light-up probe discriminating an extensive panel of parallel G4s while it is non-fluorescent in the aggregated state. The squaraine can form an unconventional sandwich π-complex binding two quadruplexes, which leads to a strongly fluorescent (Φ_F=0.61) supramolecular architecture. SQgl is highly selective against non-quadruplex and non-parallel G4 sequences without altering their topology, as desired for applications in selective in vivo high-resolution imaging and theranostics.     

Folding and Unfolding of Exogenous G-Rich Oligonucleotides in Live Cells by Fluorescence Lifetime Imaging Microscopy of o-BMVC Fluorescent Probe

Guanine-rich oligonucleotides (GROs) can self-associate to form G-quadruplex (G4) structures that have been extensively studied in vitro. To translate the G4 study from in vitro to in live cells, here fluorescence lifetime imaging microscopy (FLIM) of an o-BMVC fluorescent probe is applied to detect G4 structures and to study G4 dynamics in CL1-0 live cells. FLIM images of exogenous GROs show that the exogenous parallel G4 structures that are characterized by the o-BMVC decay times (≥2.4 ns) are detected in the lysosomes of live cells in large quantities, but the exogenous nonparallel G4 structures are hardly detected in the cytoplasm of live cells. In addition, similar results are also observed for the incubation of their single-stranded GROs. In the study of G4 formation by ssHT23 and hairpin WT22, the analyzed binary image can be used to detect very small increases in the number of o-BMVC foci (decay time ≥ 2.4 ns) in the cytoplasm of live cells. However, exogenous ssCMA can form parallel G4 structures that are able to be detected in the lysosomes of live CL1-0 cells in large quantities. Moreover, the photon counts of the o-BMVC signals (decay time ≥ 2.4 ns) that are measured in the FLIM images are used to reveal the transition of the G4 formation of ssCMA and to estimate the unfolding rate of CMA G4s with the addition of anti-CMA into live cells for the first time. Hence, FLIM images of o-BMVC fluorescence hold great promise for the study of G4 dynamics in live cells.     

In Situ Self-Assembly of Fluorogenic RNA Nanozipper Enables Real-Time Imaging of Single Viral mRNA Translation

Real-time visualization of individual viral mRNA translation activities in live cells is essential to obtain critical details of viral mRNA dynamics and to detect its transient responses to environmental stress. Fluorogenic RNA aptamers are powerful tools for real-time imaging of mRNA in live cells, but monitoring the translation activity of individual mRNAs remains a challenge due to their intrinsic photophysical properties. Here, we develop a genetically encoded turn-on 3,5-difluoro-4-hydroxybenzylidene imidazolinone (DFHBI)-binding RNA nanozipper with superior brightness and high photostability by in situ self-assembly of multiple nanozippers along single mRNAs. The nanozipper enables real-time imaging of the mobility and dynamic translation of individual viral mRNAs in live cells, providing information on the spatial dynamics and translational elongation rate of viral mRNAs.     

A Flexible Terpyridine Derivative Interacts Specifically with G‐Quadruplexes

G‐quadruplexes formed by nucleic acids are implicated in pathologies ranging from cancers to neurodegenerative diseases. We evaluated interactions of 29 bi‐ and terpyridine derivatives with G‐quadruplexes and duplexes. FRET‐melting, circular dichroism, and ¹H NMR spectroscopy showed that one terpyridine derivative interacted very selectively with G‐quadruplexes. This G‐quadruplex ligand inhibited helicase activity and should influence G‐quadruplex‐related biological processes.     

Live‐Cell Imaging of Endogenous mRNAs with a Small Molecule

Determination of subcellular localization and dynamics of mRNA is increasingly important to understanding gene expression. A new convenient and versatile method is reported that permits spatiotemporal imaging of specific non‐engineered RNAs in living cells. The method uses transfection of a plasmid encoding a gene‐specific RNA aptamer, combined with a cell‐permeable synthetic small molecule, the fluorescence of which is restored only when the RNA aptamer hybridizes with its cognitive mRNA. The method was validated by live‐cell imaging of the endogenous mRNA of β‐actin. Application of the technology to mRNAs of a total of 84 human cytoskeletal genes allowed us to observe cellular dynamics of several endogenous mRNAs including arfaptin‐2, cortactin, and cytoplasmic FMR1‐interacting protein 2. The RNA‐imaging technology and its further optimization might permit live‐cell imaging of any RNA molecules.     

Carbohydrate–DNA Interactions at G‐Quadruplexes: Folding and Stability Changes by Attaching Sugars at the 5′‐End

Quadruplex DNA structures are attracting an enormous interest in many areas of chemistry, ranging from chemical biology, supramolecular chemistry to nanoscience. We have prepared carbohydrate–DNA conjugates containing the oligonucleotide sequences of G‐quadruplexes (thrombin binding aptamer (TBA) and human telomere (TEL)), measured their thermal stability and studied their structure in solution by using NMR and molecular dynamics. The solution structure of a fucose–TBA conjugate shows stacking interactions between the carbohydrate and the DNA G‐tetrad in addition to hydrogen bonding and hydrophobic contacts. We have also shown that attaching carbohydrates at the 5′‐end of a quadruplex telomeric sequence can alter its folding topology. These results suggest the possibility of modulating the folding of the G‐quadruplex by linking carbohydrates and have clear implications in molecular recognition and the design of new G‐quadruplex ligands.     

DNA Triplexes‐Guided Assembly of G‐Quadruplexes for Constructing Label‐free Fluorescent Logic Gates

Assembly of G‐quadruplexes guided by DNA triplexes in a controlled manner is achieved for the first time. The folding of triplex sequences in acidic conditions brings two separated guanine‐rich sequences together and subsequently a G‐quadruplex structure is formed in the presence of K⁺. Based on this novel platform, label‐free fluorescent logic gates, such as AND, INHIBIT, and NOR, are constructed with ions as input and the fluorescence of a G‐quadruplex‐specific fluorescent probe NMM as output.