Fluorometry studies of aptamers that bind intrinsically fluorescent ligands: techniques, obstacles and optimizations

Intrinsic fluorescence analysis is a sensitive technique to gain insight about aptamer-small molecule interactions.Employing fluorescence properties of the ligand, the binding affinities of the aptamer-ligand complex can be quantified in the nM to mM range with great accuracy and precision. Here, we present a detection method for aptamer-ligand binding analysis that is based on the inherent fluorescence of the ligand. Further, we discuss how to optimize and resolve some common experimental challenges

Analysis of the role played by ligand-induced folding of the cocaine-binding aptamer in the photochrome aptamer switch assay

The Photochrome Aptamer Switch Assay (PHASA) relies on ligand binding by an aptamer to alter the local environment of a stilbene compound covalently attached to the 5’ end of the aptamer. We used the PHASA with both structure switching and non-structure switching versions of the cocaine-binding aptamer. We show that the largest change in fluorescence intensity and the lowest concentration limit of detection (CLooD) is obtained using the structure-switching cocaine-binding aptamer. Fluorescence anisotropy measurements were used to quantify the affinity of the conjugated aptamer to cocaine. We also used thermal melt analysis and Nuclear Magnetic Resonance (NMR) spectroscopy to show that the addition of the stilbene to the aptamer increases the melt temperature of the cocaine-bound structure-switching aptamer by (6.4 ± 0.3) °C compared to the unconjugated aptamer while the free form of the structure-switching aptamer-stilbene conjugate remains unfolded

Visible Fluorescent Light-up Probe for DNA Three-Way Junctions Provides Host−Guest Biosensing Applications

DNA three-way junctions (3WJs) consist of a Y-shaped hydrophobic branch point connecting three double-stranded stems and are viewed as druggable targets for cancer treatment. They are also important building blocks for the construction of DNA nanostructures and serve as recognition elements for DNA aptasensors for a wide variety of diagnostic applications. However, visible fluorescent light-up probes for specific staining of DNA 3WJs are currently lacking. Herein, we report that a merocyanine containing the N-methylbenzothiazolium (Btz) acceptor vinyl linked to a 2-fluorophenolic (FPhO) donor (FPhOBtz) serves as a universal fluorescent turn-on dye for DNA 3WJs. Our evidence is based on a multifaceted approach to define the specificity and affinity of FPhOBtz for 3WJ DNA aptamers; the cocaine binding aptamer MN4, the cholic acid binding aptamer (CABA), and four steroid aptamers (DOGS.1, DISS.1, BES.1, DCAS.1). FPhOBtz exhibits impressive turn-on (up to 730-fold) fluorescence at 580 nm upon aptamer binding with low micromolar affinity. Direct FPhOBtz displacement from the 3WJ binding domain through competitive alkaloid and steroid binding provides immediate fluorescent read out for host−guest detection strategies in human blood serum in the low micromolar regime. Our results present the first visible light-up fluorescent probe for DNA 3WJ detection strategies

Development of a thermal-stable structure-switching cocaine-binding aptamer

We have developed a new cocaine-binding aptamer variant that has a significantly higher melt tem- perature when bound to a ligand than the currently used sequence. Retained in this new construct is the ligand-induced structure-switching binding mechanism that is important in biosensing applications of the cocaine-binding aptamer. Isothermal titration calorimetry methods show that the binding affinity of this new sequence is slightly tighter than the existing cocaine-binding aptamer. The improved thermal performance, a Tm increase of 4 C for the cocaine-bound aptamer and 9 C for the quinine-bound aptamer, was achieved by optimizing the DNA sequence in stem 2 of the aptamer to have the highest stability based on the nearest neighbor thermodynamic parameters and confirmed by UV and fluores- cence spectroscopy. The sequences in stem 1 and stem 3 were unchanged in order to retain the structure switching and ligand binding functions. The more favorable thermal stability characteristics of the OR3 aptamer should make it a useful construct for sensing applications employing the cocaine-binding aptamer system

Redox Reporter - Ligand Competition to Support Signaling in the Cocaine-Binding Electrochemical Aptamer-Based Biosensor

Electrochemical aptamer-based (E-AB) biosensors have demonstrated capabilities in monitoring molecules directly in undiluted complex matrices and in the body with the hopes of addressing personalized medicine challenges. This sensing platform relies on an electrode-bound, redox- reporter-modified aptamer. The electrochemical signal is thought to originate from the aptamer undergoing a binding- induced conformational change capable of moving the redox reporter closer to the electrode surface. While this is the generally accepted mechanism, it is notable that there is limited evidence demonstrating conformational change or distance-dependent change in electron transfer rates in E-AB sensors. In response, we investigate here the signal transduction of the well-studied cocaine-binding aptamer with different analytical methods and found that this sensor relies on a redox-reporter - ligand competition mechanism rather than a ligand-induced structure formation mechanism. Our results show that the covalently bound redox reporter, methylene blue, binds at or near the ligand binding site on the aptamer resulting in a folded conformation of the cocaine-binding aptamer. Addition of ligand then competes with the redox reporter for binding, altering its electron transfer rate. While we show this for the cocaine-binding aptamer, given the prevalence of methylene blue in E-AB sensors, a similar competition-based may occur in other systems

Optimizing Stem Length To Improve Ligand Selectivity in a Structure-Switching Cocaine-Binding Aptamer

Understanding how aptamer structure and function are related is crucial in the design and development of aptamer-based biosensors. We have analyzed a series of cocaine-binding aptamers with different lengths of their stem 1 in order to understand the role that this stem plays in the ligand-induced structure-switching binding mechanism utilized in many of the sensor applications of this aptamer. In the cocaine-binding aptamer, the length of stem 1 controls whether the structure-switching binding mechanism for this aptamer occurs or not. We varied the length of stem 1 from being one to seven base pairs long and found that the structural transition from unfolded to folded in the unbound aptamer is when the aptamer elongates from 3 to 4 base pairs in stem 1. We then used this knowledge to achieve new binding selectivity of this aptamer for quinine over cocaine by using an aptamer with a stem 1 two base pairs long. This selectivity is achieved by means of the greater affinity quinine has for the aptamer compared with cocaine. Quinine provides enough free energy to both fold and bind the 2-base pair-long aptamer while cocaine does not. This tuning of binding selectivity of an aptamer by reducing its stability is likely a general mechanism that could be used to tune aptamer specificity for tighter binding ligands