Recent Advances in DNA Nanostructures Applied in Sensing Interfaces and Cellular Imaging

Dual-mode ultrasensitive detection of acute leukemia gene Pax-5a based on smart DNA programmed dendrimer

Accurate and sensitive detection of Pax-5a gene is the basis of early diagnosis and prediction of acute leukemia. This research aims to develop a universal dual-mode sensing method enables ultrasensitive gene detection based on smart control of DNA amplification by nucleic acid beacons e to form programmed dendrimer. The Pax-5a target gene triggers the opening of smart gate hairpin probe (Hp), exposing the stem sequence as the primer to bind with padlock probe for rolling circle amplification (RCA). The generated long strand RCA product contains a large number of functional regions that induce hybridization chain reaction (HCR) between two hairpin sequences and finally grow to form DNA dendrimer. For signal generation, the fluorescence sensing mode is based on the fluorescence recovery of the fluorophore during DNA dendrimer formation. The electrochemical sensing mode is based on the intercalation of electroactive methylene blue (MB) molecules into the DNA dendrimer which bind onto the electrode by capture probe. Comparing this novel approach to the conventional HCR and RCA, the signal can be enhanced multiple times. In addition, the dual-mode sensing strategy showed ultra-sensitivity, good selectivity, simple operation and could be used for complex substrate environment analysis offering a wide range of applications in clinical diagnosis and bioanalysis.

Dual-Accelerated Signal Amplification in Biosensing via Spatial Confining Catalytic Hairpin Assembly-Activated Spherical CRISPR/Cas12a System for Trans-Cleavage of Hairpin DNA Reporters

MicroRNAs (miRNAs) are small noncoding RNAs that regulate gene expression and are implicated in various diseases, including cancer. Due to their critical role in diagnostics, there is a growing need for sensitive, specific, and rapid detection methods for miRNAs. In this study, we present a dual-accelerated signal amplification platform for miRNA biosensing, which integrates spatial confining catalytic hairpin assembly (SC-CHA) with spherical CRISPR/Cas12a (S-CRISPR/Cas12a) system for (SC-CHA@S-CRISPR/Cas12a) trans-cleavage of hairpin DNA reporters. The method employs a biotinylated palindrome-rich assembly sequence (PAS) to form DNA nanoballs, which serve as a scaffold for the operation of SC-CHA upon miRNA binding. The SC-CHA products bind with crRNA and Cas 12a protein, activating S-CRISPR/Cas12a system to cleave the hairpin DNA reporter and generate a detectable fluorescence signal. The uniqueness of this system lies in the combined use of DNA nanoballs and hairpin DNA reporters, both of which significantly accelerate reaction kinetics, resulting in rapid signal generation. Additionally, the spherical DNA nanostructure, integrated with the S-CRISPR/Cas12a system, greatly enhances biostability and accelerating reaction kinetics. These features enable the platform to exhibit high sensitivity, with a limit of detection (LOD) as low as 13.75 fM, and excellent specificity, successfully distinguishing miRNA-21 from other miRNAs. The assay is also biostable, demonstrating reliable performance in complex biological samples such as human serum. This dual-acceleration approach offers a promising solution for sensitive, rapid, and specific miRNA biosensing, with potential applications in early cancer diagnosis and clinical monitoring.

Folding Competition and Dynamic Transformation in DNA Origami: Parallel Versus Antiparallel Crossovers

DNA is a versatile abiomaterial for constructing nanostructures with biomedical and biotechnological applications. Among the methods available, DNA origami is a robust and widely recognized technique. Traditionally, most origami designs adopt antiparallel crossovers in both scaffold and staple strands, with less emphasis on parallel crossovers, which offer advantages like enhanced nuclease resistance and single-strand routing potential. Here, a DNA origami nanostructure is designed, featuring two rotational panels that can be locked into configurations based on either antiparallel or parallel crossovers. By systematically varying the length and arrangement of these key staples, 36 pairs of antiparallel and parallel designs are studied in competitive folding tests, providing insights into the relative preference for each design. The 12 antiparallel and parallel designs are ranked, their folding pathways are examined, and nuclease resistance is assessed. The results reveal that the arrangement of staples near the central scaffold crossover is crucial for shifting between parallel and antiparallel conformations. Additionally, a two-way isothermal transformation between antiparallel and parallel origami driven by toehold-mediated displacement reactions is demonstrated, highlighting the potential of parallel designs as dynamic nanodevices for temperature-sensitive environments. This study offers valuable insights into - dynamics in antiparallel and parallel DNA origami, opening opportunities for designing  nanodevices based on parallel crossovers.

In Situ Intracellular Autocatalytic Hairpin Assembly of the Y-Shaped DNA Nanostructure for miR-155 Sensing and Gene Silencing

miR-155 is a class of cancer markers closely related to cancer metastasis and invasion. Combining in situ detection with gene silencing not only helps to analyze the information on the abundance and spatial location of microRNA expression in the cell but also synergizes the therapy. In this work, we prepared HD@CM vesicles with three hairpin DNAs by using MCF-7 cell membranes. The hairpin DNAs can be triggered by endogenous miR-155, which opens the autocatalytic molecular circuit (ACHA) and obtains Y-shaped DNA nanostructures. This nanostructure not only detects endogenous miR-155 with high sensitivity for in situ imaging but also enables gene regulation of intracellular survivin mRNA. The levels of miR-155 in MDA-MB-231, MCF-7, Hela, and HEK-293T cells are found to be 7703, 3978, 1696, and 1229 copies/cell, respectively, as detected by HD@CMs. The fluorescence produced by HD@CM after coincubation with different cells is found to be proportional to the intracellular miR-155 content by confocal imaging. In addition, the gene regulatory function of the Y-shaped DNA structure resulted in significant inhibition of survivin protein expression and apoptosis rates of up to 83%. We look forward to the future application of our HD@CM platform for the precise diagnosis and programmable treatment of clinical cancers.

Ultrasensitive Electrochemiluminescence Biosensing Platform Based on Polymer Dots with Aggregation-Induced Emission for Dual-Biotoxin Assay

Multitarget assay has always been a hot topic in electrochemiluminescence (ECL) methods. Herein, a "on-off-on" ECL aptasensor was developed for the ultrasensitive and sequential detection of possible biological warfare agents, deoxynivalenol (DON) and abrin (ABR). As a luminophore, polymer dots (Pdots) with aggregation-induced emission exhibit high ECL efficiency in the aptasensor, i.e., the signal "on" state. The DON assays mainly depend on ECL quenching due to the efficient quenching effect between ferrocene-H2-ferrocene (Fc-H2-Fc) and Pdots, i.e., the signal "off" state. When the aptasensor is incubated with the oligonucleotide sequence S2 to replace Fc-H2-Fc, obvious ECL recovery occurs, i.e., the signal "on" state, which can be used to sequentially detect ABR. The limit of detection (LOD) for DON is 0.73 fg·mL-1 in the range of 5.0 to 50 ng·mL-1; and the LOD for ABR is ∼0.38 pg·mL-1 in the range of 1.25 pg·mL-1 to 1.25 μg·mL-1. The as-designed ECL aptasensor exhibits good stability and reproducibility, high specificity, and favorable practicality. Therefore, this work provides a new approach for assays of DON and ABR in food safety and can be used as a model to design an ultrasensitive ECL biosensor for multitarget detection.

Magnetic beads and GO-assisted enzyme-free signal amplification fluorescent biosensors for disease diagnosis

Cancer detection is still a major challenge in public health. Identification of oncogene is the first step toward solving this problem. Studies have revealed that various cancers are associated with miRNA expression. Therefore, the sensitive detection of miRNA is substantially important to solve the cancer problem. In this study, let-7a, a representative substance of miRNA, was selected as the detection target. With the assistance of magnetic beads commonly used in biosensors and self-synthesized graphene oxide materials, specificity and sensitivity detection of the target gene let-7a were achieved via protease-free signal amplification. The limit of detection (LOD) was as low as 15.015pM. The fluorescence signal intensity showed a good linear relationship with the logarithm of let-7a concentration. The biosensor could also detect let-7a in complex human serum samples. Overall, this fluorescent biosensor is not only simple to operate, but also strongly specificity to detect let-7a. Therefore, it has substantial potential for application in the early diagnosis of clinical medicine and biological research.

DNA polyhedrons cube, prism, and square pyramid protect the catalytic activity of catalase: A thermodynamics and kinetics study

DNA is widely used as building block material for the construction of polyhedral nanostructures. DNA polyhedrons (DNA prism, cube, and square pyramid) are small 3D wireframed nanostructures with tunable shapes and sizes. Despite substantial progress in synthesis, the study regarding cellular responses to DNA polyhedrons is limited. Herein, the molecular interaction between DNA polyhedrons and the antioxidant enzyme, catalase has been explored. The enzymatic activity of bovine liver catalase (BLC) remains unaltered in the presence of DNA polyhedrons after 1 h of incubation. However, the activity of BLC was protected after 24 h of incubation in the presence of DNA polyhedrons as compared to the natural unfolding. The kinetics study confirmed the protective role of DNA polyhedrons on BLC with lower KM and higher catalytic efficiency. Furthermore, no profound conformational changes of BLC occur in the presence of DNA polyhedrons as observed in spectroscopic studies. From fluorescence quenching data we confirmed the binding between DNA polyhedrons and BLC. The thermodynamic parameters indicate that non-covalent bonds played a major role during the interaction of BLC with DNA polyhedrons. Moreover, the hepatic catalase activity remains unaltered in the presence of DNA polyhedrons. The cytotoxicity assay revealed that DNA polyhedrons were biocompatible in the cellular environment. The protective role of DNA polyhedrons on enzyme activity and the unaltered conformational change of protein ensures the biocompatibility of DNA polyhedrons in the cellular environment.

DNA Nanomachine-Driven Heterogeneous Quadratic Amplification for Sensitive and Programmable miRNA Profiling

Inspired by the molecular crowding effect in biological systems, a novel heterogeneous quadratic amplification molecular circuit (HEQAC) was developed for sensitive bimodal miRNA profiling (HEQAC-BMP) by combining an MNAzyme-based DNA nanomachine with an entropy-driven catalytic hairpin assembly (E-CHA) autocatalytic circuit. Utilizing ferromagnetic nanomaterials as the substrate for DNA nanomachines, a biomimetic heterogeneous interface was established; thus, a localized molecular crowding system was created that can elevate the local reaction concentration and accelerate the molecular recognition process for a significant threshold signal. Simultaneously, the threshold signal undergoes further amplification by E-CHA and is transformed into a chemical signal, enabling a colorimetric-fluorescence bimodal signal readout. The HEQAC-BMP enables miRNA detection from 10 aM to 10 nM with detection limits of 3.7 aM (colorimetry) and 4.8 aM (fluorometry), respectively. Moreover, the design principle and strategy of HEQAC-BMP can be customized to address other critical viruses or diseases with life-threatening and socioeconomic impacts, enhancing healthcare outcomes for individuals.

AuPt Nanodonuts as a Novel Coreaction Accelerator and Luminophore for a Label-free Electrochemiluminescence Aptasensor

Novel and effective coreaction accelerators are of great importance in electrochemiluminescence (ECL) systems. In this work, novel AuPt nanodonuts, i.e., SnS2 quantum dots (QDs)/Cys-AuPt heterogeneous nanorings (NRs), serve as both a highly effective coreaction accelerator and the luminophore in a label-free ECL aptasensor. The novel AuPt nanodonuts were formed by decorating SnS2 QDs onto AuPt NR surfaces, which would promote the production of more coreactant intermediate in the SnS2 QDs/K2S2O8 system. As a result, the ECL performance was greatly improved. Meanwhile, l-cysteine (l-Cys) played an important role in the combination between AuPt NRs and SnS2 QDs, and the nanodonuts served as the matrix to load numerous lincomycin (Lin) aptamers. Under optimal conditions, the ECL aptasensor exhibited ultrasensitive detection of Lin from 1 fg/mL to 0.1 pg/mL with a limit of detection (LOD) of 0.7 fg/mL (1.72 fM).

Target-Induced AIE Effect Coupled with CRISPR/Cas12a System Dual-Signal Biosensing for the Ultrasensitive Detection of Gliotoxin

Here, a novel rapid and ultrasensitive aptamer biosensor was designed for target-induced activation of AIE effect and followed by the activation of Crispr Cas12a (LbCpf1)-mediated cleavage to achieve dual-signal detection. The prepared DNA building blocks contain the target aptamer, ssDNA-Fc, and Activator1. In this system, the activation mode was divided into two steps. First, when the target interacts with the aptamers, the DNA building blocks would be disintegrated rapidly, releasing a mass of Ac1, generating ETTC-dsDNA aggregated to produce a fluorescence signal by the AIE effect. Second, with the release of Ac2, LbCpf1-crRNA was activated, which greatly improves the ssDNA-Fc cleavage efficiency to render signal amplification and ultrasensitive detection of the target. Satisfactorily, using this approach to detect gliotoxin, optimal conditions for detection was achieved for reducing the detection time to 55 min, achieving a low detection limit of 2.4 fM and a satisfactory linear in the range of 50 fM to 1 nM, which addressed the shortcoming of a weak electrochemical signal in previous sensors. The water-insoluble AIE material was coupled with DNA to obtain water-soluble ETTC-dsDNA and successfully introduced into the sensor system, with a low detection limit of 5.6 fM. Subsequently, the biosensor combined with handheld electrochemical workstation was successfully applied in the detection of gliotoxin in five actual samples, with a detection range of 32.0 to 2.09 × 108 pM. This strategy not only provides a novel and effective detection platform for mycotoxins in complex food matrices but also opens a promising avenue for various molecules detection in imaging and disease diagnosis.

ON-OFF Fluorescent Cyanine Dye Based on a Benzothiophenyl Rotor Enables Selective Illumination of G-Quadruplexes in Mitochondria

Conventional cyanine dyes exist as "always-on" fluorescent probes leading to inevitable background signals which often limit their performance and scope of applications. To develop specific fluorescent probes with high sensitivity and robust OFF/ON switching for targeting G4s, we introduced aromatic heterocycles through conjugation with polymethine chains to construct a rotor-π system. Here, a universal strategy is presented to synthesize pentamethine cyanines with different aromatic heterocycle substituents on the meso-polymethine chain. In these probes, SN-Cy5-S is self-quenched in aqueous solution due to H-aggregation. The structure indicates that SN-Cy5-S with a flexible meso-benzothiophenyl rotor conjugated to the cyanine backbone matches adaptively with G-tetrad planes, enhancing π-π stacking and resulting in triggered fluorescence. This allows recognition of G-quadruplexes due to the synergy of disaggregation-induced emission (DIE) and inhibited twisted intramolecular charge-transfer effects. This combination leads to a robust lighting-up fluorescence response for c-myc G4 with superior fluorescence enhancement (98-fold), allowing for a low detection limit of 1.51 nM, which is much more sensitive than the previously reported DIE-based G4 probes (22-83.5 nM). In addition, the superior imaging properties and rapid internalization time (5 min) in mitochondria allow SN-Cy5-S to also have a high potential for mitochondrially targeting anti-cancer therapy.