Photo‐Tethers for the (Multi‐)Cyclic,Conformational Caging of Long Oligonucleotides

Intramolecular circularization of DNA oligonucleotides was accomplished by incorporation of alkyne‐modified photolabile nucleosides into DNA sequences, followed by a Cu^I‐catalyzed alkyne–azide cycloaddition with bis‐azido linker molecules. We determined a range of ring sizes, in which the caged circular oligonucleotides exhibit superior duplex destabilizing properties. Specific binding of a full‐length 90 nt C10 aptamer recognizing human Burkitt's lymphoma cells was then temporarily inhibited by locking the aptamer in a bicircularized structure. Irradiation restored the native aptamer conformation resulting in efficient cell binding and uptake. The photo‐tether strategy presented here provides a robust and versatile tool for the light‐activation of longer functional oligonucleotides, noteworthy without prior knowledge on the structure and the importance of specific nucleotides within a DNA aptamer.     

Photo‐Tethers for the (Multi‐)Cyclic,Conformational Caging of Long Oligonucleotides

Intramolecular circularization of DNA oligonucleotides was accomplished by incorporation of alkyne‐modified photolabile nucleosides into DNA sequences, followed by a Cu^I‐catalyzed alkyne–azide cycloaddition with bis‐azido linker molecules. We determined a range of ring sizes, in which the caged circular oligonucleotides exhibit superior duplex destabilizing properties. Specific binding of a full‐length 90 nt C10 aptamer recognizing human Burkitt's lymphoma cells was then temporarily inhibited by locking the aptamer in a bicircularized structure. Irradiation restored the native aptamer conformation resulting in efficient cell binding and uptake. The photo‐tether strategy presented here provides a robust and versatile tool for the light‐activation of longer functional oligonucleotides, noteworthy without prior knowledge on the structure and the importance of specific nucleotides within a DNA aptamer.     

Structure-switching signaling aptamers

Aptamers are single-stranded nucleic acids with defined tertiary structures for selective binding to target molecules. Aptamers are also able to bind a complementary DNA sequence to form a duplex structure. In this report, we describe a strategy for designing aptamer-based fluorescent reporters that function by switching structures from DNA/DNA duplex to DNA/target complex. The duplex is formed between a fluorophore-labeled DNA aptamer and a small oligonucleotide modified with a quenching moiety (denoted QDNA). When the target is absent, the aptamer binds to QDNA, bringing the fluorophore and the quencher into close proximity for maximum fluorescence quenching. When the target is introduced, the aptamer prefers to form the aptamer-target complex. The switch of the binding partners for the aptamer occurs in conjunction with the generation of a strong fluorescence signal owing to the dissociation of QDNA. Herein, we report on the preparation of several structure-switching reporters from two existing DNA aptamers. Our design strategy is easy to generalize for any aptamer without prior knowledge of its secondary or tertiary structure, and should be suited for the development of aptamer-based reporters for real-time sensing applications.     

Structure-switching signaling aptamers: transducing molecular recognition into fluorescence signaling

The development of aptamer technology considerably broadens the utility of nucleic acids as molecular recognition elements, because it allows the creation of DNA or RNA molecules for binding a wide variety of analytes (targets) with high affinity and specificity. Several recent studies have focused on developing rational design strategies for transducing aptamer-target recognition events into easily detectable signals, so that aptamers can be widely exploited for detection directed applications. We have devised a generalizable strategy for designing nonfluorescent aptamers that can be turned into fluorescence-signaling reporters. The resultant signaling probes are denoted "structure-switching signaling aptamers" as they report target binding by switching structures from DNA/DNA duplex to DNA/target complex. The duplex is formed between a fluorophore-labeled DNA aptamer and an antisense DNA oligonucleotide modified with a quencher (denoted QDNA). In the absence of the target, the aptamer hybridizes with QDNA, bringing the fluorophore into close proximity of the quencher for efficient fluorescence quenching. When this system is exposed to the target, the aptamer switches its binding partner from QDNA to the target. This structure-switching event is coupled to the generation of a fluorescent signal through the departure of QDNA, permitting the real-time monitoring of the aptamer-target recognition. In this article, we discuss the conceptual framework of the structure-switching approach, the essential features of structure-switching signaling aptamers as well as remaining challenges and possible solutions associated with this new methodology.     

Aptamer Biosensor for Selective and Rapid Determination of Insulin

Insulin plays an important role in glucose metabolism and its detection in biological fluids is of interest. In this study, a triple-helix molecular switch was employed for the simple, sensitive, and rapid determination of insulin. The triple-helix molecular switch was composed of a target specific aptamer sequence flanked by two arm segments and a dual-labeled oligonucleotide acting as a signal transduction probe. This approach takes advantage of unique properties of aptamers and triple-helix molecular switches such as high affinity, selectivity, and stability. In the absence of insulin, the fluorescence of triple-helix molecular switch is on. Upon addition of insulin, the aptamer binds to its target, leading to the release of the signal transduction probe, folding of the signal transduction probe to a stem loop structure, and the quenching of the fluorescence. This sensor showed a high selectivity toward insulin and a limit of detection as low as 9.97 nM. The sensor was employed for the determination of insulin in biological samples. This platform may be generalizable for a variety of molecules.     

双链荧光核酸适体探针用于蛋白质的简便快速检测

发展了一种基于双链荧光核酸适体(F-Aptamer)探针的简单快速检测蛋白质的分析方法.该双链荧光Aptamer探针由一条带荧光标记的Aptamer探针和带猝灭标记的互补DNA组成,当靶蛋白存在时,能形成比双链荧光Aptamer探针更稳定的F-Aptamer/蛋白质复合物,并发出荧光,从而实现对蛋白质的简便快速检测,检测线性范围为6~100 nmol/L,检出限为6 nmol/L.该方法设计简单,对核酸适体分子的大小和空间结构没有要求,可作为一种通用的基于F-Aptamer识别机理的蛋白质检测方法.     

Structural basis of DNA folding and recognition in an AMP-DNA aptamer complex: distinct architectures but common recognition motifs for DNA and RNA aptamers complexed to AMP

Background: Structural studies by nuclear magnetic resonance (NMR) of RNA and DNA aptamer complexes identified through in vitro selection and amplification have provided a wealth of information on RNA and DNA tertiary structure and molecular recognition in solution. The RNA and DNA aptamers that target ATP (and AMP)' with micromolar affinity exhibit distinct binding site sequences and secondary structures. We report below on the tertiary structure of the AMP-DNA aptamer complex in solution and compare it with the previously reported tertiary structure of the AMP-RNA aptamer complex in solution.Results: The solution structure of the AMP-DNA aptamer complex shows, surprisingly, that two AMP molecules are intercalated at adjacent sites within a rectangular widened minor groove. Complex formation involves adaptive binding where the asymmetric internal bubble of the free DNA aptamer zippers up through formation of a continuous six-base mismatch segment which includes a pair of adjacent three-base platforms. The AMP molecules pair through their Watson-Crick edges with the minor groove edges of guanine residues. These recognition G·A mismatches are flanked by sheared G·A and reversed Hoogsteen G·G mismatch pairs.Conclusions: The AMP-DNA aptamer and AMP-RNA aptamer complexes have distinct tertiary structures and binding stoichiometries. Nevertheless, both complexes have similar structural features and recognition alignments in their binding pockets. Specifically, AMP targets both DNA and RNA aptamers by intercalating between purine bases and through identical G·A mismatch formation. The recognition G·A mismatch stacks with a reversed Hoogsteen G·G mismatch in one direction and with an adenine base in the other direction in both complexes. It is striking that DNA and RNA aptamers selected independently from libraries of 10¹⁴ molecules in each case utilize identical mismatch alignments for molecular recognition with micromolar affinity within binding-site pockets containing common structural elements.     

Structure-switching allosteric deoxyribozymes

DNA aptamers and DNA enzymes (DNAzymes or deoxyribozymes) are single-stranded DNA molecules with ligand-binding and catalytic capabilities, respectively. Allosteric DNA enzymes (aptazymes) are deoxyribozymes whose activity can be regulated by the binding state of an appended aptamer domain and have many potential uses in the fields of drug discovery and diagnostics. In this report, we describe a simple, yet potentially general, DNA aptazyme rational design strategy that requires no structural characterization of the constituent deoxyribozymes and aptamers. It is based on the concept originally developed in our laboratory for the design of structure-switching signaling aptamers that change structural states from a DNA-DNA duplex to a DNA-target complex upon target binding. In our new strategy, an antisense oligonucleotide is used to regulate the enzymatic activity of a linked aptamer-deoxyribozyme by annealing with a stretch of nucleotides on each side of the aptamer-DNAzyme junction. Structural reorganization of the aptamer domain upon target binding relieves the suppressive effect of this regulatory oligonucleotide on the attached DNA enzyme. Consequently, the target-binding event triggers the catalytic action of the aptazyme. We have demonstrated this concept using two RNA-cleaving deoxyribozymes, each adjoined to a DNA aptamer that binds ATP. These allosteric DNA enzymes exhibit the same ligand-binding specificity as the parental DNA aptamer and show up to 30-fold rate enhancement in the presence of ATP. The described methodology provides a convenient approach for rationally designing catalytic DNA-based biosensors.     

Target-Dependent Protection of DNA Aptamers against Nucleolytic Digestion Enables Signal-On Biosensing with Toehold-Mediated Rolling Circle Amplification

We report a generalizable strategy for biosensing that takes advantage of the resistance of DNA aptamers against nuclease digestion when bound with their targets, coupled with toehold mediated strand displacement (TMSD) and rolling circle amplification (RCA). A DNA aptamer containing a toehold extension at its 5′-end protects it from 3′-exonuclease digestion by phi29 DNA polymerase (phi29 DP) in a concentration-dependent manner. The protected aptamer can participate in RCA in the presence of a circular template that is designed to free the aptamer from its target via TMSD. The absence of the target leads to aptamer digestion, and thus no RCA product is produced, resulting in a turn-on sensor. Using two different DNA aptamers, we demonstrate rapid and quantitative real-time fluorescence detection of two human proteins: platelet-derived growth factor (PDGF) and thrombin. Sensitive detection of PDGF was also achieved in human serum and human plasma, demonstrating the selectivity of the assay.     

Development of naturally selected and molecularly engineered intrachain and competitive FRET-aptamers and aptamer beacons

Several different approaches have been taken to development of homogeneous fluorescent aptamer assays including end-labeled beacons and signaling aptamers which are intrinsically quenched by nucleotides. Two new strategies dubbed "intrachain" and "competitive" FRET-aptamer assays are summarized in this review. Intrachain and competitive FRET-aptamers can be engineered on the molecular level through a series exploratory experiments involving prior knowledge of aptamer secondary or tertiary structures and hypotheses about aptamer conformational changes. However, there is an intrinsic risk of altering aptamer affinity or specificity associated with chemical modifications of an aptamer. Natural selection methods for FRET-aptamers have also been devised to potentially obviate the chemical modification problem. The naturally selected aptamers are subjected to fluorophore (F)- and or quencher (Q)-conjugated nucleotide triphosphate (NTP) incorporation by polymerase chain reaction (PCR) with permissive polymerases such as Deep Vent exo-, but still demonstrate sensitive and specific assay performance despite modified bases, because they are ultimately selected after decoration with F and Q. This paper summarizes work in this area and presents some new examples of the engineered and naturally selected FRET-aptamers for detection of vitamin D.     

Ultra-sensitive Detecting OPs-Isocarbophos Using Photoinduced Regeneration of Aptamer-based Electrochemical Sensors

Residues related to organophosphorus pesticides (OPs) may be hazardous to food and environmental safety. Isocarbophos (ICP) is one of the most highly toxic OPs that had been banned in China and strictly limited in many other countries for use on vegetables and fruits. However, illegal use often occurs in agricultural production due to its good control effect. Developing a sensitive method is an urgent need to determine trace ICP. Herein, an electrochemical aptasensor was fabricated for ICP detection, which combines the advantages of the high affinity of aptamer with photo-triggered azobenzene to realize the sensor's regeneration. In this work, the aptamer was labeled with ferrocene group (Fc) at the 3′-end and modified on the surface of the electrode as a recognition element for specific detection of ICP. Two azobenzene groups were inserted at the 5′-end of the aptamer. Upon ultraviolet light irradiation, the configuration of azobenzene altered from trans-to-cis, and two units of ICP dissociated with aptamer by the unfolding of its hairpin structure to achieve the sensor's regeneration. Based on this strategy, the current response recorded of the aptasensor increases with the increasing of ICP concentration. The differential pulse voltammogram (DPV) signals are linear with the logarithm of ICP concentration in a range from 10 pM to 10 μM. The limit of detection is 3 pM (S/N=3). After 6 times of regeneration, the signal intensity for ICP could keep over 95 % to the first time of detection. The aptasensor was also successfully applied to the ICP analysis in tomato to validate stability and applicability, with an average recovery rate of 76.2 %–119.3 % and a relative standard deviation (RSD) of 1.8 %–10.7 %. To the best of our knowledge, this study was the first time using a simple incubation procedure, to realize sensitive and reversible detection of ICP, meanwhile which expected to be applied to the ICP's toxicological research.     

A pH-responsive activatable aptamer probe for targeted cancer imaging based on i-motif-driven conformation alteration

We present here a p H-responsive activatable aptamer probe for targeted cancer imaging based on i-motif-driven conformation alteration. This p H-responsive activatable aptamer probe is composed of two single-stranded DNA. One was used for target recognition, containing a central, target specific aptamer sequence at the 3′-end and an extension sequence at the 5′-end with 5-carboxytetramethylrhodamine(TAMRA) label(denoted as strand A). The other(strand I), being competent to work on the formation of i-motif structure, contained four stretches of the cytosine(C) rich domain and was labeled with a Black Hole Quencher 2(BHQ2) at the 3′-end. At neutral or slightly alkaline p H, strand I was hybridized to the extension sequence of strand A to form a double-stranded DNA probe, termed i-motif-based activatable aptamer probe(I-AAP). Because of proximityinduced energy transfer, the I-AAP was in a "signal off" state. The slightly acidic p H enforced the strand I to form an intramolecular i-motif and then initiated the dehybridization of I-AAP, leading to fluorescence readout in the target recognition. As a demonstration, AS1411 aptamer was used for MCF-7 cells imaging. It was displayed that the I-AAP could be carried out for target cancer cells imaging after being activated in slightly acidic environment. The applicability of I-AAP for tumor tissues imaging has been also investigated by using the isolated MCF-7 tumor tissues. These results implied the I-AAP strategy is promising as a novel approach for cancer imaging.     

A Universal DNA Aptamer that Recognizes Spike Proteins of Diverse SARS-CoV-2 Variants of Concern

We report on a unique DNA aptamer, denoted MSA52, that displays universally high affinity for the spike proteins of wildtype SARS-CoV-2 as well as the Alpha, Beta, Gamma, Epsilon, Kappa, Delta and Omicron variants. Using an aptamer pool produced from round 13 of selection against the S1 domain of the wildtype spike protein, we carried out one-round SELEX experiments using five different trimeric spike proteins from variants, followed by high-throughput sequencing and sequence alignment analysis of aptamers that formed complexes with all proteins. A previously unidentified aptamer, MSA52, showed K_d values ranging from 2 to 10 nM for all variant spike proteins, and also bound similarly to variants not present in the reselection experiments. This aptamer also recognized pseudotyped lentiviruses (PL) expressing eight different spike proteins of SARS-CoV-2 with K_d values between 20 and 50 pM, and was integrated into a simple colorimetric assay for detection of multiple PL variants. This discovery provides evidence that aptamers can be generated with high affinity to multiple variants of a single protein, including emerging variants, making it well-suited for molecular recognition of rapidly evolving targets such as those found in SARS-CoV-2.     

ADLOC: An Aptamer‐Displacement Assay Based on Luminescent Oxygen Channeling

Functional nucleic acids, such as aptamers and allosteric ribozymes, can sense their ligands specifically, thereby undergoing structural alterations that can be converted into a detectable signal. The direct coupling of molecular recognition to signal generation enables the production of versatile reporters that can be applied as molecular probes for various purposes, including high‐throughput screening. Here we describe an unprecedented type of a nucleic acid‐based sensor system and show that it is amenable to high‐throughput screening (HTS) applications. The approach detects the displacement of an aptamer from its bound protein partner by means of luminescent oxygen channeling. In a proof‐of‐principle study we demonstrate that the format is feasible for efficient identification of small drug‐like molecules that bind to a protein target, in this case to the Sec7 domain of cytohesin. We extended the approach to a new cytohesin‐specific single chain DNA aptamer, C10.41, which exhibits a similar binding behavior to cytohesins but has the advantage of being more stable and easier to synthesize and to modify than the RNA‐aptamer M69. The results obtained with both aptamers indicate the general suitability of the aptamer‐displacement assay based on luminescent oxygen channelling (ADLOC) for HTS. We also analyzed the potential for false positive hits and identified from a library of 18 000 drug‐like small molecules two compounds as strong singlet‐oxygen quenchers. With full automation and the use of commercially available plate readers, we estimate that the ADLOC‐based assay described here could be used to screen at least 100 000 compounds per day.     

SAR by MS

RNAs have recently emerged as an exciting new target for small molecule therapeutics. Conventional HTS discovery strategies measuring disruption of RNAprotein interactions have proven unsuccessful. We describe a ligand-based drug discovery strategy that addresses the inherent difficulties RNA targets. The strategy is based on: 1) using a MS spectrometry (MS)-based assay to measure the affinity of compounds for a target; 2) performing competitive binding experiments and molecular modeling with the motifs to determine the binding site(s) of the ligands; 3) design and synthesis of derivatives of interesting binders to establish the linking sites; 4) identifying the appropriate linker group using MS; 5) fusing motifs into a more complex structure to afford higher affinity compounds. Example of applying this strategy to identify new classes of lead molecules with affinity and specificity for ribosomal RNA targets will be presented.     

Principal factors that determine the extension of detection range in molecular beacon aptamer/conjugated polyelectrolyte bioassays

A strategy to extend the detection range of weakly-binding targets is reported that takes advantage of fluorescence resonance energy transfer (FRET)-based bioassays based on molecular beacon aptamers (MBAs) and cationic conjugated polyelectrolytes (CPEs). In comparison to other aptamer-target pairs, the aptamer-based adenosine triphosphate (ATP) detection assays are limited by the relatively weak binding between the two partners. In response, a series of MBAs were designed that have different stem stabilities while keeping the constant ATP-specific aptamer sequence in the loop part. The MBAs are labeled with a fluorophore and a quencher at both termini. In the absence of ATP, the hairpin MBAs can be opened by CPEs via a combination of electrostatic and hydrophobic interactions, showing a FRET-sensitized fluorophore signal. In the presence of ATP, the aptamer forms a G-quadruplex and the FRET signal decreases due to tighter contact between the fluorophore and quencher in the ATP/MBA/CPE triplex structure. The FRET-sensitized signal is inversely proportional to [ATP]. The extension of the detection range is determined by the competition between opening of the ATP/MBA G-quadruplex by CPEs and the composite influence by ATP/aptamer binding and the stem interactions. With increasing stem stability, the weak binding of ATP and its aptamer is successfully compensated to show the resistance to disruption by CPEs, resulting in a substantially broadened detection range (from millimolar up to nanomolar concentrations) and a remarkably improved limit of detection. From a general perspective, this strategy has the potential to be extended to other chemical- and biological-assays with low target binding affinity.     

Screening and preliminary application of a DNA aptamer for rapid detection of Salmonella O8

We report on a rapid method for the detection of Salmonella O8. It does not require an enrichment step but rather uses an aptamer as a probe that was selected by system evolution of ligands by exponential enrichment (SELEX) assay. Firstly, aptamer against Salmonella O8 was selected from a 78 bp random DNA library that was prepared in-vitro. The binding ability of the aptamers to target bacterium was examined by aptamer-linked immobilized sorbent assay. A high affinity aptamer was successfully selected from the initial random DNA pool, and its secondary structure was also investigated. Next, this high affinity aptamer B10 was used to recognize Salmonella O8 via fluorescence microscopy. The selected aptamer has a high specificity and high affinity against its target. We believe that the resulting fluorescence in-situ labeling assay is a potentially useful alternative in rapid screening and detection of foodborne pathogens.

Tuning Riboswitch‐Mediated Gene Regulation by Rational Control of Aptamer Ligand Binding Properties

Riboswitch‐mediated control of gene expression depends on ligand binding properties (kinetics and affinity) of its aptamer domain. A detailed analysis of interior regions of the aptamer, which affect the ligand binding properties, is important for both understanding natural riboswitch functions and for enabling rational design of tuneable artificial riboswitches. Kinetic analyses of binding reaction between flavin mononucleotide (FMN) and several natural and mutant aptamer domains of FMN‐specific riboswitches were performed. The strong dependence of the dissociation rate (52.6‐fold) and affinity (100‐fold) on the identities of base pairs in the aptamer stem suggested that the stem region, which is conserved in length but variable in base‐pair composition and context, is the tuning region of the FMN‐specific aptamer. Synthetic riboswitches were constructed based on the same aptamer domain by rationally modifying the tuning regions. The observed 9.31‐fold difference in the half‐maximal effective concentration (EC₅₀) corresponded to a 11.6‐fold difference in the dissociation constant (K_D) of the aptamer domains and suggested that the gene expression can be controlled by rationally adjusting the tuning regions.     

Cocaine detection by structure-switch aptamer-based capillary zone electrophoresis

Aptamers, which are nucleic acid oligonucleotides that can bind targets with high affinity and specificity, have been widely applied as affinity probes in capillary electrophoresis (CE). Due to relative weak interaction between aptamers and small molecules, the application of aptamer-based CE is still limited in certain compounds. A new strategy that is based on the aptamer structure-switch concept was designed for small molecule detection by a novel CE method. A carboxyfluorescein (fluorescein amidite, FAM) label DNA aptamer was first incubated with partial complementary strand (CS), and then the free aptamer and the aptamer-CS duplex were well separated and determined by metal cation mediated CE/laser-induced fluorescence. When the target was introduced into the incubated sample, the hybridized form was destabilized, resulting in the changes of the fluorescence intensities of the free aptamer and the aptamer-CS duplex. The length of CS was investigated and 12 mer CS showed the best sensitivity for the detection of cocaine. The presented CE-LIF method, which combines the separation power of CE with the specificity of interactions occurring between target, aptamer, and CS, could be a universal detection strategy for other aptamer-specified small molecules.     

Highly Specific Recognition of Guanosine Using Engineered Base-Excised Aptamers

Purines and their derivatives are highly important molecules in biology for nucleic acid synthesis, energy storage, and signaling. Although many DNA aptamers have been obtained for binding adenine derivatives such as adenosine, adenosine monophosphate, and adenosine triphosphate, success for the specific binding of guanosine has been limited. Instead of performing new aptamer selections, we report herein a base-excision strategy to engineer existing aptamers to bind guanosine. Both a Na⁺-binding aptamer and the classical adenosine aptamer have been manipulated as base-excising scaffolds. A total of seven guanosine aptamers were designed, of which the G16-deleted Na⁺ aptamer showed the highest bindng specificity and affinity for guanosine with an apparent dissociation constant of 0.78 mm . Single monophosphate difference in the target molecule was also recognizable. The generality of both the aptamer scaffold and excised site were systematically studied. Overall, this work provides a few guanosine binding aptamers by using a non-SELEX method. It also provides deeper insights into the engineering of aptamers for molecular recognition.