Enzyme-Free Dynamic DNA Reaction Networks for On-Demand Bioanalysis and Bioimaging

Enzyme- and DNAzyme-Driven Transient Assembly of DNA-Based Phase-Separated Coacervate Microdroplets

An assembly of dissipative, transient, DNA-based microdroplet (MD) coacervates in the presence of auxiliary enzymes (endonucleases and nickases) or MD-embedded DNAzyme is introduced. Two pairs of different Y-shaped DNA core frameworks modified with toehold tethers are cross-linked by complementary toehold-functionalized duplexes, engineered to be cleaved by EcoRI or HindIII endonucleases, or cross-linked by palindromic strands that include pre-engineered Nt.BbvCI or Nb.BtsI nicking sites, demonstrating transient evolution/depletion of phase-separated MD coacervates. By mixing the pairs of endonuclease- or nickase-responsive MDs, programmed or gated transient formation/depletion of MD frameworks is presented. In addition, by cross-linking a pre-engineered Y-shaped core framework with a sequence-designed fuel strand, phase separation of MD coacervates with embedded Mg2+-DNAzyme units is introduced. The DNAzyme-catalyzed cleavage of a ribonucleobase-modified hairpin substrate, generating the waste product of the metabolite fragments, leads to the metabolite-driven separation of the cross-linked coacervates, resulting in the temporal evolution and depletion of the DNAzyme-functionalized MDs. By employing a light-responsive caged hairpin structure, the light-modulated fueled evolution and depletion of the DNAzyme-active MDs are presented. The enzyme- or DNAzyme-catalyzed transient evolution/depletion of the MD coacervates provides protocell frameworks mimicking dynamic transient processes of native cells. The possible application of MDs as functional carriers for the temporal, dose-controlled release of loads is addressed.

Target-Triggered Cascaded Self-Feedback DNAzyme Circuit Loaded in ZIF-8 for Highly Sensitive miRNA Imaging in Living Cells

The highly sensitive and rapid imaging of miRNA in living cells promises to advance our understanding of diseases and promote their diagnosis and treatment. To enhance the sensitivity of miRNA imaging, a series of cascade signal amplification strategies based on enzyme-free methods have been developed. However, these cascaded amplification strategies involve complex designs and multiple amplification mechanisms, leading to potential side effects. Herein, we have developed a novel hairpins@ZIF-8 nanosystem by rationally integrating ZIF-8 with a cascaded self-feedback DNAzyme circuit (CSDC), achieving highly sensitive and rapid imaging of miRNA in living cells. ZIF-8 facilitates the efficient transfection of nucleic acid probes into cells and provides the necessary cofactor ions for CSDC. The developed CSDC possesses exponential amplification based solely on the DNAzyme mechanism. Benefiting from the exponential amplification efficiency, the CSDC exhibited higher sensitivity than traditional DNAzyme-based amplification, with a detection limit of 2.28 fM, approximately 105 times more sensitive than traditional DNAzyme-based amplification. This hairpins@ZIF-8 nanosystem demonstrated strong practical application capabilities, effectively reflecting fluctuations in intracellular miRNA levels and successfully distinguishing between normal and tumor cells based on miRNA expression differences. It could also be applied for in vivo miRNA imaging. This proposed strategy is anticipated to pave the way for innovative amplification approaches and serve as a vital instrument in miRNA-related research, diagnosis, and treatment.

Harnessing Demethylase-Regulated Catalytic DNA Circuit for In-Situ Investigation of the Regulatory Connection with MicroRNA

Insight into the epigenetic modulation-correlated molecule interactions has significant implications for the in-depth understanding of intracellular intricate biological networks. However, there is currently a lack of reliable biological tools for elucidating the potential correlation between epigenetic regulators and relevant genes, e.g., microRNAs (miRNAs). Herein, an alkB homologue 5 (ALKBH5, a key epigenetic regulator)-modulated catalytic DNA circuit (ACD) was constructed by grafting a N6-methyladenosine (m6A)-caged I-R3 DNAzyme into the circuitry components for achieving the on-site miRNA imaging in living cells. Specifically, the catalytic activity of I-R3 DNAzyme could be effectively suppressed by the m6A modification situated at its highly sequence-conserved core region and then be selectively restored through the ALKBH5-mediated demethylation pathway. And the ALKBH5-activated I-R3 DNAzyme allowed the highly efficient DNA cleaving reaction in the presence of DNAzyme cofactors, resulting in the liberation of catalytic hairpin assembly (CHA) reactants. Subsequently, target miRNA triggered the CHA circuit to produce a duplex DNA product while releasing the miRNA analyte. The liberated miRNA could autonomously trigger the next round of the CHA assembly cycle for generating the amplified fluorescence readout. By virtue of the stimuli-responsive activation and the CHA amplification circuit, the ACD system achieved highly specific and sensitive imaging of miRNA in tumor cells. Moreover, this efficiently and reliably ALKBH5-activated DNA circuit is demonstrated to reveal the underlying relationship between activator ALKBH5 and miRNA. Overall, the developed ACD system provides a promising tool for the robust on-site profiling of epigenetic-involved signal pathways, thus displaying great potential in bioanalytical applications.

Self-Replicating Catalytic Hybridization Assembly of Bipedal DNAzyme Walkers for Enhanced Electrochemiluminescence Bioanalysis

Dynamic DNA nanodevices, particularly DNA walkers, have proven to be versatile tools for target recognition, signal conversion, and amplification in biosensing. However, their ability to detect low-abundance analytes in complex biological samples is often compromised by limited amplification depth and severe signal leakage. To address these challenges, we developed a simple yet highly efficient strategy to engineer a self-replicating bipedal DNAzyme (SEDY) walker for sensitive and selective electrochemiluminescence (ECL) bioanalysis. Unlike conventional DNA walkers that are typically constructed by catalytic DNA assembly in a single direction, the SEDY walker integrates a self-replicating feedback mechanism that greatly enhances both the selectivity and sensitivity of bioanalysis. First, the SEDY walker is assembled through a target-triggered, enzyme-free, self-replicating catalytic approach, minimizing the risk of undesired side reactions and signal leakage by simplifying reactant complexity. Furthermore, the SEDY walker features newly exposed trigger sequences that facilitate its autonomous replication, leading to a robust and exponential amplification of its products. Our experiments demonstrate that the SEDY walker can sensitively and selectively detect acetamiprid by navigating specific probes within cross-shaped DNA orbits. The ECL biosensor offers a linear detection range from 1 × 10-15 M to 1 × 10-9 M, with a limit of detection as low as 5.8 × 10-16 M. We anticipate that the SEDY walker will be a powerful tool for detecting various analytes in biological applications.

Endogenous Glutathione-Activated Nucleic Acid Molecular Circuitry for Cell-Specific MicroRNA Imaging

Sensitive and reliable microRNA imaging in living cells has significant implications for clinical diagnosis and monitoring. Catalytic DNA circuits have emerged as potent tools for tracking these intracellular biomarkers and probing the corresponding biochemical processes. However, their utility is hindered by the low resistance to external interference, leading to undesired off-site activation and consequent signal leakage. Therefore, achieving the endogenous control of the DNA circuit's activation is preferable to the reliable target analysis in living cells. In this study, we attempted to address this challenge by engineering a simple yet effective endogenous glutathione (GSH)-regulated hybridization chain reaction (HCR) circuit for acquiring high-contrast miRNA imaging. Initially, the HCR hairpin reactants were blocked by the engineered disulfide-integrated DNA duplex, thus effectively passivating their sensing function. And the precaged HCR hairpin was liberated by the cell-specific GSH molecule, thus initiating the HCR system for selectively amplified detection of microRNA-21 (miR-21). This approach prevented unwanted signal leakage before exposure into target cells, thus ensuring robust miR-21 imaging with high accuracy and reliability in specific tumor cells. Moreover, the endogenously responsive HCR circuit established a link between the small regulatory factors and miRNA, thereby enhancing the signal gain. In summary, the endogenously activatable DNA circuit represents a versatile toolbox for robust bioanalysis and exploration of potential signaling pathways in living cells.

A Methylation-Gated DNAzyme Circuit for Spatially Controlled Imaging of MicroRNA in Cells and Animals

Epigenetic modification plays an indispensable role in regulating routine molecular signaling pathways, yet it is rarely used to modulate molecular self-assembly networks. Herein, we constructed a bioorthogonal demethylase-stimulated DNA circuitry (DSC) system for high-fidelity imaging of microRNA (miRNA) in live cells and mice by eliminating undesired off-site signal leakage. The simple and robust DSC system is composed of a primary cell-specific circuitry regulation (CR) module and an ultimate signal-transducing amplifier (SA) module. After the modularly designed DSC system was delivered into target live cells, the DNAzyme of the CR module was site-specifically activated by endogenous demethylase to produce fuel strands for the subsequent miRNA-targeting SA module. Through the on-site and multiply guaranteed molecular recognitions, the lucid yet efficient DSC system realized the reliably amplified in vivo miRNA sensing and enabled the in-depth exploration of the demethylase-involved signal pathway with miRNA in live cells. Our bioorthogonally on-site-activated DSC system represents a universal and versatile biomolecular sensing platform via various demethylase regulations and shows more prospects for more different personalized theragnostics.

Multiply Guaranteed Catalytic DNA Circuit for Cancer-Cell-Selective Imaging of miRNA and Robust Evaluation of Drug Resistance

Catalytic DNA circuits are desirable for sensitive bioimaging in living cells; yet, it remains a challenge to monitor these intricate signal communications because of the uncontrolled circuitry leakage and insufficient cell selectivity. Herein, a simple yet powerful DNA-repairing enzyme (APE1) activation strategy is introduced to achieve the site-specific exposure of a catalytic DNA circuit for realizing the selectively amplified imaging of intracellular microRNA and robust evaluation of the APE1-involved drug resistance. Specifically, the circuitry reactants are firmly blocked by the enzyme recognition/cleavage site to prevent undesirable off-site circuitry leakage. The caged DNA circuit has no target-sensing activity until its circuitry components are activated via the enzyme-mediated structural reconstitution and finally transduces the amplified fluorescence signal within the miRNA stimulation. The designed DNA circuit demonstrates an enhanced signal-to-background ratio of miRNA assay as compared with the conventional DNA circuit and enables the cancer-cell-selective imaging of miRNA. In addition, it shows robust sensing performance in visualizing the APE1-mediated chemoresistance in living cells, which is anticipated to achieve in-depth clinical diagnosis and chemotherapy research.