Fluorophore Cy5 Research Articles

One‐Step Maleimide‐Based Dual Functionalization of Protein N‐Termini

Maleimide derivatives are privileged reagents for chemically modifying proteins through the Michael addition reaction with cysteine due to their selectivity, operational simplicity, and commercial availability. However, since accessible free cysteine is rarely found in natural proteins, it is highly desirable to find alternative targets to enable direct bioconjugation of proteins with maleimides. In this study, we have developed an operationally simple and straightforward method for the N‐terminal modification of proteins without the need for mutagenesis via a copper(II)‐mediated [3+2] cycloaddition reaction with maleimides and 2‐pyridinecarboxaldehyde (2‐PCA) derivatives under non‐denaturing conditions at pH 6 and 37 °C in aqueous media. Our method utilizes commercially available maleimides to attach diverse functionalities to various N‐terminal amino acids. We demonstrate the preparation of a ternary protein complex cross‐linked at the N‐termini and dually modified trastuzumab equipped with monomethyl auristatin E (MMAE), a cytotoxic agent, and a Cy5 fluorophore (MMAE–Cy5–trastuzumab). MMAE–Cy5–trastuzumab retained human epidermal growth factor receptor 2 (HER2) recognition activity and exerted cytotoxicity against HER2‐positive cells. Furthermore, MMAE–Cy5–trastuzumab allowed successful visualization of HER2‐positive cancer cells in mouse tumors. This straightforward method will expand the accessibility of protein conjugates with well‐defined structures in a wide range of research fields.

One-Step Maleimide-Based Dual Functionalization of Protein N-Termini.

Maleimide derivatives are privileged reagents for chemically modifying proteins through the Michael addition reaction with cysteine due to their selectivity, operational simplicity, and commercial availability. However, since accessible free cysteine is rarely found in natural proteins, it is highly desirable to find alternative targets to enable direct bioconjugation of proteins with maleimides. In this study, we have developed an operationally simple and straightforward method for the N-terminal modification of proteins without the need for mutagenesis via a copper(II)-mediated [3+2] cycloaddition reaction with maleimides and 2-pyridinecarboxaldehyde (2-PCA) derivatives under non-denaturing conditions at pH 6 and 37 °C in aqueous media. Our method utilizes commercially available maleimides to attach diverse functionalities to various N-terminal amino acids. We demonstrate the preparation of a ternary protein complex cross-linked at the N-termini and dually modified trastuzumab equipped with monomethyl auristatin E (MMAE), a cytotoxic agent, and a Cy5 fluorophore (MMAE-Cy5-trastuzumab). MMAE-Cy5-trastuzumab retained human epidermal growth factor receptor 2 (HER2) recognition activity and exerted cytotoxicity against HER2-positive cells. Furthermore, MMAE-Cy5-trastuzumab allowed successful visualization of HER2-positive cancer cells in mouse tumors. This straightforward method will expand the accessibility of protein conjugates with well-defined structures in a wide range of research fields.

The Acid-Stimulated Self-Assembled DNA Nanonetwork for Sensitive Detection and Living Cancer Cell Imaging of MicroRNA-221.

Herein, a novel functional DNA structure, acid-stimulated self-assembly DNA nanonetwork (ASDN), was proposed for miRNA-221 sensitive detection and high-resolution living cancer cell imaging. Significantly, the self-assembly of ASDN only occurred in the acidic extracellular environment of cancer cells, which could be endocytosed by cancer cells to eliminate the interference of noncancer cells and deliver the ASDN into cancer cells. Subsequently, endogenous miRNA-221 could trigger the catalytic hairpin assembly within ASDN, resulting in the separation of the fluorophore Cy5 and the quencher BHQ2 to recover the substantial Cy5 fluorescence signals, thus achieving signal amplification for sensitive detection of miRNA-221 with a detection limit of 5.5 pM, as well as facilitating high-resolution and low-background imaging of miRNA-221 in cancer cells. In consequence, this strategy provides an innovative DNA nanonetwork to distinguish cancer cells from other cells for sensitive detection of biomarkers, offering a meaningful reference for the application of DNA nanostructure self-assembly technology in relevant fundamental research and disease diagnosis.

Tetrahedral DNA-Based Ternary Recognition Ratiometric Fluorescent Probes for Real-Time In Situ Resolving Lysosome Subpopulations in Living Cells via Cl-, Ca2+, and pH.

Lysosomes are multifunctional organelles vital for cellular homeostasis with distinct subpopulations characterized by varying levels of Cl-, Ca2+, and H+. In situ visualization of these parameters is crucial for lysosomal research, yet developing probes that can simultaneously detect multiple ions remains challenging. Herein, we developed a lysosome-targeting ternary recognition ratiometric fluorescent probe based on tetrahedral DNA nanostructures (TDNs) to analyze lysosome subpopulations by Cl-, Ca2+, and pH. The TDN probe is assembled from four single-stranded DNAs, each end-modified with responsive fluorophores (Pr-Cl for Cl-, Pr-Ca for Ca2+, and Pr-pH for pH) or a reference fluorophore (Cy5). The fluorophores are integrated at the vertices of the rigid TDN to minimize mutual interference, and their fixed stoichiometry establishes a robust ternary recognition ratiometric fluorescence sensor for in situ resolution of lysosome subpopulations in living cells. Accordingly, a rise in lysosome subpopulations 2/6 characterized by low [Cl-], medium/high [Ca2+], and high pH was observed in the Niemann-Pick disease model cells but seldom observed in the control group. Conversely, there was a marked decline in the fraction of subpopulations 1/4/5 characterized by high [Cl-], medium to low [Ca2+], and pH. These changes were substantially reversed upon treatment. The probe holds great promise for studying lysosome subpopulations and the diagnosis and treatment of related diseases.

Nuclease-induced stepwise photodropping (NISP) to precisely investigate single-stranded DNA degradation behaviors of exonucleases and endonucleases.

Here, we employed a fluorescence-based single molecule method called nuclease-induced stepwise photodropping (NISP) to measure in realtime the DNA degradation mediated by mitochondrial genome maintenance exonuclease 1 (MGME1), a bidirectional single-stranded DNA (ssDNA)-specific exonuclease. The method detects a stepwise decrease in fluorescence signals from Cy3 fluorophores labeled on an immobilized DNA substrate. Using NISP, we successfully determined the DNA degradation rates of 6.3±0.4and 2.0±0.1 nucleotides (nt) s-1 for MGME1 in the 5'-to-3' and 3'-to-5' directions, respectively. These results provide direct evidence of the stronger 5' directionality of MGME1, consistent with its established role in mitochondrial DNA maintenance. Importantly, when we employed NISP to investigate mung bean nuclease, an ss-specific endonuclease, we observed a markedly different NISP pattern, suggesting a distributive cleavage activity of the enzyme. Furthermore, we applied NISP to determine the ssDNA degradation behavior of the double-stranded-specific exonuclease, λexonuclease. These findings underscore the capability of NISP to accurately and reliably measure the degradation of ssDNA by both exo- and endonucleases. Here, we demonstrate NISP as a powerful tool for investigating the ssDNA degradation behavior of nucleases at the single-molecule level.

Binding Behavior of Human Hepatoma-Derived Growth Factor on SMYD1.

The protein-induced fluorescence change technique was employed to investigate the interactions between proteins and their DNA substrates modified with the Cy3 fluorophore. It has been reported that the human hepatoma-derived growth factor (HDGF), containing the chromatin-associated N-terminal proline-tryptophan-tryptophan-proline (PWWP) domain (the N-terminal 100 amino acids of HDGF) capable of binding the SMYD1 promoter, participates in various cellular processes and is involved in human cancer. This project investigated the specific binding behavior of HDGF, the PWWP domain, and the C140 domain (the C-terminal 140 amino acids of HDGF) sequentially using protein-induced fluorescence change. We found that the binding of HDGF and its related proteins on Cy3-labeled 15 bp SMYD1 dsDNA will cause a significant decrease in the recorded Cy3 fluorophore intensity, indicating the occurrence of protein-induced fluorescence quenching. The dissociation equilibrium constant was determined by fitting the bound fraction curve to a binding model. An approximate 10-time weaker SMYD1 binding affinity of the PWWP domain was found in comparison to HDGF. Moreover, the PWWP domain is required for DNA binding, and the C140 domain can enhance the DNA binding affinity. Furthermore, we found that the C140 domain can regulate the sequence-specific binding capability of HDGF on SMYD1.

Optofluidic photonic crystal fiber platform for sensitive and reliable fluorescence based biosensing.

Biosensing plays a pivotal role in various scientific domains, offering significant contributions to medical diagnostics, environmental monitoring, and biotechnology. Fluorescence biosensing relies on the fluorescence emission from labelled biomolecules to enable sensitive and selective identification and quantification of specific biological targets in various samples. Photonic crystal fibers (PCFs) have led to the development of optofluidic fibers enabling efficient light-liquid interaction within small liquid volume. Herein, we present the development of a user-friendly optofluidic-fiber platform with simple hardware requirements for sensitive and reliable fluorescence biosensing with high measurement repeatability. We demonstrate a sensitivity improvement of the fluorescence emission up to 17 times compared to standard cuvette measurement, with a limit of detection of Cy5 fluorophore as low as 100 pM. The improvement in measurement repeatability is exploited for detecting haptoglobin protein, a relevant biomarker to diagnose several diseases, by using commercially available Cy5 labelled antibodies. The study aims to showcase an optofluidic platform leveraging the benefits provided by optofluidic fibers, which encompass easy light injection, robustness, and high sensitivity.

Gene silencing in the aedine cell lines C6/36 and U4.4 using long double-stranded RNA

BackgroundRNA interference (RNAi) is a target-specific gene silencing method that can be used to determine gene functions and investigate host–pathogen interactions, as well as facilitating the development of ecofriendly pesticides. Commercially available transfection reagents (TRs) can improve the efficacy of RNAi. However, we currently lack a product and protocol for the transfection of insect cell lines with long double-stranded RNA (dsRNA).MethodsWe used agarose gel electrophoresis to determine the capacity of eight TRs to form complexes with long dsRNA. A CellTiter-Glo assay was then used to assess the cytotoxicity of the resulting lipoplexes. We also measured the cellular uptake of dsRNA by fluorescence microscopy using the fluorophore Cy3 as a label. Finally, we analyzed the TRs based on their transfection efficacy and compared the RNAi responses of Aedes albopictus C6/36 and U4.4 cells by knocking down an mCherry reporter Semliki Forest virus in both cell lines.ResultsThe TRs from Biontex (K4, Metafectene Pro, and Metafectene SI+) showed the best complexing capacity and the lowest dsRNA:TR ratio needed for complete complex formation. Only HiPerFect was unable to complex the dsRNA completely, even at a ratio of 1:9. Most of the complexes containing mCherry-dsRNA were nontoxic at 2 ng/µL, but Lipofectamine 2000 was toxic at 1 ng/µL in U4.4 cells and at 2 ng/µL in C6/36 cells. The transfection of U4.4 cells with mCherry-dsRNA/TR complexes achieved significant knockdown of the virus reporter. Comparison of the RNAi response in C6/36 and U4.4 cells suggested that C6/36 cells lack the antiviral RNAi response because there was no significant knockdown of the virus reporter in any of the treatments.ConclusionsC6/36 cells have an impaired RNAi response as previously reported. This investigation provides valuable information for future RNAi experiments by showing how to mitigate the adverse effects attributed to TRs. This will facilitate the judicious selection of TRs and transfection conditions conducive to RNAi research in mosquitoes.Graphical

Single primer/self-template-powered isothermal amplification for single-molecule quantification of multiple DNA glycosylases

DNA glycosylase assumes a pivotal role in the preservation of genome integrity by recognizing and excising damaged bases. Herein, we develop a single primer/self-template-powered cascade rolling circle amplification (RCA) and apurinic/apyrimidinic endonuclease (APE1)-mediated signal amplification for simultaneous detection of human alkyladenine DNA glycosylase (hAAG) and uracil DNA glycosylase (UDG). The uniqueness of this approach lies in the use of custom-designed hairpin probes to establish a prerequisite for RCA: the conformational change of hairpin probe to circular template, which effectively suppress undesired non-specific amplification. We design two hairpin probes featuring elongated stem structure and 3′-phosphate (3′-PO4) modifications. The stems of hairpin probes are modified with glycosylase substrates and BER process can cleave hairpin probes, resulting in the generation of single-stranded DNAs (ssDNAs) with 3′-hydroxyl (3′-OH) ends. These ssDNAs can function as padlock probes to form circular template upon ligation by ligase. Ultimately, the self-template-initiated RCA and APE1-mediated signal amplification cascade occurs, generating a substantial number of free Cy3 and Cy5 fluorophores that can be simply visualized by single-molecule fluorescence detection. This method demonstrates excellent specificity and sensitivity, with a limit of detection (LOD) of 3.42 × 10-12 U/μL for hAAG and 2.41 × 10-12 U/μL for UDG. This method also can be used for screening of potential inhibitor and kinetic parameter measurement. Most importantly, this method enables accurate profiling of glycosylases expression levels in various cancer cell lines and detection of glycosylase activities at the single-cell level, offering a bright future in cancer detection, medical research, and precision medicine.

A fluorescence aptamer sensor utilizing WS2 nanosheets for sensitive detection of patulin: enhanced specificity and wide applicability.

A tungsten disulfide (WS2) nanosheet-based aptamer sensor was developed to detect patulin (PAT). The 5'-end of the PAT aptamer was modified with a cyanine 3 (Cy3) fluorophore, which self-assembled on WS2 nanosheets. The interaction between the Cy3 fluorophore at the 5'-end of the PAT aptamer and the WS2 nanosheets resulted in reduced fluorescence (FL) intensity due to fluorescence resonance energy transfer (FRET). The introduction of PAT into this sensing system led to hybridization with the PAT aptamer, forming a G-quadruplex/PAT complex with low affinity for the WS2 nanosheet surface. This hybridization increased the distance between the Cy3 fluorophore and the WS2 nanosheets, inhibiting FRET and producing a strong FL signal. Under optimal experimental conditions, the FL intensity of the sensing system demonstrated an excellent linear correlation with PAT concentrations ranging from 0.5 to 40.0 ng mL-1, and it achieved a detection limit (S/N = 3) of 0.23 ng mL-1. This sensing system offers enhanced specificity for PAT detection and has the potential for broad application in detecting other toxins by substituting the sequence of the recognition aptamer.

Tracking and recording of intracellular oxygen concentration changes in cell organelles: preparation and function of azide-modified fluorescent probes.

Tracking hypoxic environments and changes in oxygen levels contribute to the elucidation of pathological mechanisms. In this study, we attempted to design molecular probes that can be activated to show fluorescence under hypoxic conditions and that can move to specific cell organelles. Considering that azide groups were selectively reduced to primary amines by reductases under hypoxic conditions, we prepared Hoechst and fluorophore Cy-5 derivatives with azide groups (Hoechst-N3 and Cy-N3) as hypoxia probes. Hoechst-N3 and Cy-N3 showed weak fluorescence, but once activated in the cytosol of hypoxic cells, they exhibited robust fluorescence and then moved to their target organelles, the cell nucleus and mitochondria. In addition, when these probes were administered to the cells in the proper sequence, each probe was activated in response to the intracellular oxygen concentration at that point and exhibited oxygen concentration-dependent fluorescence at the target organelle. By measuring the fluorescence intensity of the cell nucleus and mitochondria, we successfully traced the history of changes in intracellular oxygen levels. Thus, we achieved tracking and recording of oxygen status in the cells.

Fluorescence Bar-Coding and Flowmetry Based on Dark State Transitions in Fluorescence Emitters.

Reversible dark state transitions in fluorophores represent a limiting factor in fluorescence-based ultrasensitive spectroscopy, are a necessary basis for fluorescence-based super-resolution imaging, but may also offer additional, largely orthogonal fluorescence-based readout parameters. In this work, we analyzed the blinking kinetics of Cyanine5 (Cy5) as a bar-coding feature distinguishing Cy5 from rhodamine fluorophores having largely overlapping emission spectra. First, fluorescence correlation spectroscopy (FCS) solution measurements on mixtures of free fluorophores and fluorophore-labeled small unilamellar vesicles (SUVs) showed that Cy5 could be readily distinguished from the rhodamines by its reversible, largely excitation-driven trans-cis isomerization. This was next confirmed by transient state (TRAST) spectroscopy measurements, determining the fluorophore dark state kinetics in a more robust manner, from how the time-averaged fluorescence intensity varies upon modulation of the applied excitation light. TRAST was then combined with wide-field imaging of live cells, whereby Cy5 and rhodamine fluorophores could be distinguished on a whole cell level as well as in spatially resolved, multiplexed images of the cells. Finally, we established a microfluidic TRAST concept and showed how different mixtures of free Cy5 and rhodamine fluorophores and corresponding fluorophore-labeled SUVs could be distinguished on-the-fly when passing through a microfluidic channel. In contrast to FCS, TRAST does not rely on single-molecule detection conditions or a high time resolution and is thus broadly applicable to different biological samples. Therefore, we expect that the bar-coding concept presented in this work can offer an additional useful strategy for fluorescence-based multiplexing that can be implemented on a broad range of both stationary and moving samples.

Novel fluorescence nano-orbital biosensor for highly sensitive microRNA detection

BackgroundMicroRNAs play an important role in regulating cell function and gene expression. Early prevention and clinical diagnosis of diseases have high requirements for high-sensitivity detection of microRNAs. Due to the limitations of tedious operation and large sample size, miRNA with small molecular weight and low expression abundance cannot be accurately detected in traditional miRNA detection. To improve the sensitivity and accuracy of detection, we established a novel biosensor based on nucleic acid circuit of signal amplification, which converted miRNA recognition into a fluorescence signal for amplification. ResultsWe designed a biosensor based on an exponential amplification reaction with cascaded HCR and DNAzyme nucleic acid circuit (named E-NOF biosensor) by amplicon sub-fragments to trigger the construction of fluorescence nano-orbitals (NOF), which could be used to detect miRNA ultrasensitively. By modifying two fluorophores (Cy3 and Cy5) on the chain of constructing nano-orbitals, when the amplicon triggered the construction of nano-orbitals, fluorescence resonance energy transfer (FRET) occurred between Cy3 and Cy5, and then two fluorescence signals with different trends could be observed. Therefore, through the ratio of the two signals, we could quantitatively and quickly detect the miRNA from 1 fM to 100 nM, and the E-NOF biosensor detection limit was as low as 0.129 fM. Furthermore, the HCR nucleic acid circuit cascaded with DNAzyme could enrich the fluorophores on the nano-orbitals and significantly enhance the fluorescence signal by accelerating the reaction rate. SignificanceAccording to our understanding, the E-NOF biosensor is the first strategy to cascade EXPAR with HCR and DNAzyme nucleic acid circuit for miRNA-1246 detection. Accurate results can be obtained in only 120 min. Compared with the traditional HCR system, the sensitivity of the new E-NOF biosensor is increased by 1 × 109 times. Furthermore, the biosensor can also detect biomarkers in human serum samples. It has great potential in miRNA detection and identification.

Demethylation-Driven ligase chain reaction for simultaneously sensitive detection of m6A demethylase FTO and m1A demethylase ALKBH3 in breast cancer at Single-Molecule level

RNA demethylases play a crucial role in gene expression regulation by controlling RNA methylation levels, and their abnormal expressions are associated with many human diseases. Herein, we develop a single-molecule detection method for simultaneous quantification of N6-methyladenosine (m6A) demethylase FTO and N1-methyladenosine (m1A) demethylase ALKBH3 based on RNA demethylation-directed multi-cyclic ligase chain reaction (LCR) cascades. We design a ssDNA containing m6A modification as the substrate of FTO and a ssDNA containing m1A modification as the substrate of ALKBH3. FTO and ALKBH3 catalyze the demethylation of m6A and m1A to generate normal adenine (A), respectively. Afterwards, Taq ligase initiates the LCR reaction with the demethylated ssDNAs as the templates to produce abundant biotinylated Cy3/Cy5-labeled signal probes. Subsequently, the resultant biotinylated probes are captured by streptavidin-coated magnetic beads (MBs) to form the MB-ssDNA-Cy3/Cy5 complexes. After magnetic separation, the ssDNAs in the MB-ssDNA-Cy3/Cy5 complexes are digested by DNase I, liberating abundant Cy3 and Cy5 fluorophores that can be counted by single-molecule detection. Remarkably, only a single DNA ligase is employed to achieve target signal conversion and multi-cyclic cascade amplification. This method displays extremely high sensitivity with a limit of detection of 6.33 × 10−18 mol/L for FTO and 1.44 × 10−17 mol/L for ALKBH3. Moreover, it can measure the enzyme kinetic parameters, screen inhibitors, and quantify cellular FTO and ALKBH3 activities with single-cell sensitivity. Furthermore, it can differentiate the FTO and ALKBH3 levels in the tissues of healthy human and breast cancer patients, offering a robust platform for biomedical research and clinical diagnosis.

B-241 A Novel Approach to Develop Multiplex Loop Mediated Amplification (LAMP) Assays

Abstract Background Loop mediated amplification (LAMP) technology is a sensitive, accurate and rapid method for point-of-care (POC) molecular diagnostic detection. One disadvantage is that current LAMP methods can detect only one target per reaction whereas in a standard real-time PCR assay, multiple targets (3–4) can be detected in a single reaction. This is because current methods of detection for amplification products in a LAMP assay are not sequence-specific. Common detection methods include turbidity, use of color-changing dye or intercalating dye in the reaction mix, gel electrophoresis, etc. These methods are not sequence-specific and, thus, unable to differentiate between targets if amplified in a single tube, with the exception of lateral flow devices or melt analysis, which add time, complexity, and cost. To overcome this challenge, we have developed a novel method which simplifies development of multiplex LAMP without use of any additional primers/probes/reagents or steps. Methods Triplex RT-LAMP assay was developed for rapid detection of foot-and-mouth disease virus (FMDV) at POC. For this, LAMP primers targeting two different regions of 3D pol gene of FMDV were designed. For use as internal control (IC), LAMP primers were also designed targeting a conserved region of the bovine 18S rRNA gene. For multiplexing, best performing primer sets for each target were labelled with a unique fluorophore at 5′ end and a quencher (BHQ-1) at 3′ end. FMDV-1 primers were labeled with Cy5 fluorophore, FMDV-2 primers were labelled with Texas Red (TxR) fluorophore, and 18S rRNA with FAM fluorophore. Triplex RT-LAMP assay was performed using a specially formulated Multiplex Isothermal Master Mix but without any intercalating dye added to the mix. All 3 primer mixes were added to the Master Mix and reactions were carried out in a real-time thermocycler at 72°C for 30 min, with data collected every 30 seconds. Reaction kinetics were monitored as an increase in fluorescence associated with the accumulation of double-stranded DNA in respective channels (FAM for 18S rRNA, Cy5 for FMDV-1, and TxR for FMDV-2). Assay sensitivity was determined by testing 10-fold serial dilution of respective template, individually as well as mixed together. Results Results obtained showed feasibility of triplex RT-LAMP assay for simultaneous detection of 3 targets in a single reaction. Sensitivity and specificity of triplex RT-LAMP was comparable to control reactions (RT-LAMP assay with intercalating dye) for each target. No cross reactivity or non-specific amplification was observed with any of the primer designs. Conclusions This newly developed method allows detection of up to 3 targets in a single reaction without affecting the assay performance. This method is much easier to develop and optimize than previously reported methods as it uses standard LAMP primers without need of any additional primers/probes.

Development of a N6-methyladenosine-directed single quantum dot-based biosensor for sensitive detection of METTL3/14 complex activity in breast cancer tissues

The METTL3/14 complex is an important RNA N6-Methyladenosine (m6A) methyltransferase in organisms, and the abnormal METTL3/14 complex activity is associated with the pathogenesis and various cancers. Sensitive detection of METTL3/14 complex is essential to tumor pathogenesis study, cancer diagnosis, and anti-cancer drug discovery. However, traditional methods for METTL3/14 complex assay suffer from poor specificity, costly antibodies, unstable RNA substrates, and low sensitivity. Herein, we construct a single quantum dot (QD)-based förster resonance energy transfer (FRET) biosensor for sensitive detection of METTL3/14 complex activity. In the presence of METTL3/14 complex, it catalyzes the methylation of adenine in the substrate probe, leading to the formation of m6A that protects the substrate probes from MazF-mediated cleavage. The hybridization of methylated DNA substrate with biotinylated capture probe initiates polymerization reaction to obtain a biotinylated double-stranded DNA (dsDNA) with the incorporation of numerous Cy5 fluorophores. Subsequently, the Cy5-incorporated dsDNA can self-assembly onto the 605QD surface to form the 605QD-dsDNA-Cy5 nanostructure, causing FRET between 605QD donor and Cy5 acceptor. This biosensor has excellent sensitivity with a limit of detection (LOD) of 3.11 × 10−17 M, and it can measure the METTL3/14 complex activity in a single cell. Moreover, this biosensor can be used to evaluate the METTL3/14 complex kinetic parameters and screen potential inhibitors. Furthermore, it can differentiate the METTL3/14 complex expression in healthy human tissues and breast cancer patient tissues, providing a powerful tool for cancer pathogenesis study, clinical diagnosis, prognosis monitoring, and drug discovery.

RNA methylation-driven assembly of fluorescence-encoded nanostructures for sensitive detection of m6A modification writer METTL3/14 complex in human breast tissues

N6-methyladenosine (m6A) is an ubiquitous post-transcriptional modification catalyzed by METTL3/14 complex in eukaryotic mRNAs. The abnormal METTL3/14 complex activity affects multiple steps of RNA metabolism and may induce various diseases. Herein, we demonstrate the RNA methylation-driven assembly of fluorescence-encoded nanostructures for sensitive detection of m6A modification writer METTL3/14 complex in human breast tissues. METTL3/14 complex can catalyze the methylation of RNA probe to prevent it from being cleaved by MazF. The intact RNA probe is recognized by the magnetic bead (MB)-capture probe conjugates to induce duplex-specific nuclease (DSN)-assisted cyclic digestion, exposing numerous shorter ssDNAs with 3′-OH end. The shorter ssDNAs on the MB surface can act as the primers to initiate terminal deoxynucleotidyl transferase (TdT)-enhanced tyramide signal amplification (TSA), forming the Cy5 fluorescence-encoded nanostructures. After magnetic separation, the Cy5 fluorescence-encoded nanostructures are digested by DNase I to release abundant Cy5 fluorophores that can be simply quantified by fluorescence measurement. This assay achieves good specificity and high sensitivity with a detection limit of 58.8 aM, and it can screen METTL3/14 complex inhibitors and quantify METTL3/14 complex activity at the single-cell level. Furthermore, this assay can differentiate the METTL3/14 complex level in breast cancer patient tissues and healthy volunteer tissues.

Construction of a Quantum-Dot-Based FRET Nanosensor through Direct Encoding of Streptavidin-Binding RNA Aptamers for N6-Methyladenosine Demethylase Detection.

N6-Methyladenosine (m6A) demethylases can catalyze the removal of the methyl modification on m6A, and it is closely associated with the occurrence, proliferation, differentiation, and metastasis of malignancies. The m6A demethylases (e.g., fat mass and obesity-associated protein (FTO)) may act as a cancer biomarker and are crucial for anticancer drug screening and early clinical diagnosis. Herein, we demonstrate the construction of a quantum-dot-based Förster resonance energy-transfer (FRET) nanosensor through direct encoding of streptavidin-binding RNA aptamers (SA aptamers) for m6A demethylase detection. This nanosensor employs multiple Cy5-molecule-labeled SA aptamers as the building materials to construct the 605QD-RNA-Cy5 nanoassembly, and it exploits the hinder effect of m6A upon elongation and ligation reactions to distinguish m6A-containing RNA probes from demethylated RNA probes. When m6A demethylase is present, the m6A-containing RNA probes are demethylated to generate the demethylated RNA probes, initiating strand extension and ligation reactions to yield a complete transcription template for SA aptamers. Subsequently, a T7-assisted cascade transcription amplification reaction is activated to transcribe abundant SA aptamers with the incorporation of multiple Cy5 fluorophores. The Cy5-incorporated SA aptamers can self-assembly onto the streptavidin-coated 605QD surface to obtain the 605QD-SA aptamer-Cy5 nanoassemblies, resulting in the generation of distinct FRET signals. This nanosensor exhibits ultrahigh sensitivity and excellent specificity, and it can detect endogenous FTO at the single-cell level. Furthermore, this nanosensor can precisely measure enzyme kinetic parameters, screen m6A demethylase inhibitors, and differentiate the FTO expression between breast cancer patients and healthy individual tissues, offering a versatile platform for clinical diagnostic and drug discovery.

Rapid ultrasensitive detection of methamphetamine based on the FRET mechanism between apta-nanobiosensor based on CdTe/ZnS quantum dots and DNA-conjugated Cy3 fluorophore: Forensic biological fluids

A novel Apta- nano biosensor (ANB) based on CdTe/ZnS QDs were designed and applied for ultrasensitive determination of methamphetamine (MA) as one most addictive psychoactive substance at 1 min. Different steps of ANB formation and MA detection were reported by fluorescence spectra. In short, in the first step, the water-soluble ANB was prepared by the ligand-exchange method using the replacement of thioglycolic acid (TGA) and glutathione (GSH) molecules at the surface of QDs with thiolated MA aptamer. This phenomenon increases QDs' fluorescence intensity. In the second step, the optimal amount of DNA-conjugated Cy3 fluorophore was gradually added to obtain the mixture. Based on the fluorescence resonance energy transfer (FRET) mechanism, energy transfer from QDs to Cy3 fluorophore led to the quenching of QDs and turning on the fluorophore. Finally, by titrating different amounts of MA into this system, the thiolated labeled aptamer tends to attach to the target (MA). The Cy3 fluorophore is separated from the QD surface, which leads to the quenching of QDs and fluorophore. This quenching of the ANB could be performed based on a kind of photo-induced electron transfer (PET) mechanism. The detection limit of MA is 4.15 ± 1.08 × 10−12 mol L−1 with a dynamic range from 1.38 ± 0.75 × 10−11 to 99.98 ± 1.03 × 10−8 mol L−1. ANB was applied to determining MA in forensic biological fluids and the obtained results were evaluated with LC-MS-MS with satisfactory results.

Construction of a Single-Molecule Biosensor for Antibody-Free Detection of Locus-Specific N6-Methyladenosine in Cancer Cells and Tissues.

N6-Methyladenosine (m6A) has emerged as a key post-transcriptional regulator in mRNA metabolism, and its dysregulation is associated with multiple human diseases. Herein, we construct a single-molecule fluorescent biosensor for antibody-free detection of locus-specific m6A in cancer cells and tissues. A 5'-biotinylated capture probe and a 3'-hydroxylated assistant probe are designed for the recognition of specific m6A-mRNA. The m6A-sensitive endoribonuclease MazF can identify and cleave the unmethylated mRNA, and the retained intact m6A-mRNA can hybridize with assistant probes and capture probes to achieve sandwich hybrids. The sandwich hybrids are immobilized on magnetic beads (MBs) to initiate the terminal deoxynucleotidyl transferase (TdT)-assisted polymerization, facilitating the continuous incorporation of Cy5-dATP to form long Cy5-polyA tails for the production of an on-bead amplified fluorescence signal. After magnetic separation and exonuclease digestion, numerous Cy5 fluorophores are released and subsequently measured by single-molecule detection. Especially, this biosensor is implemented simply and isothermally without the involvement of either radiolabeling or m6A-specific antibody. Moreover, this biosensor shows ultrahigh sensitivity with a detection limit of 2.24 × 10-17 M, and it can discriminate a 0.01% m6A level from a large pool of coexisting counterparts. Furthermore, this biosensor can be used for monitoring cellular m6A-mRNA expression and differentiating the m6A level in the breast cancer patient tissues from that in the healthy person tissues, providing a new avenue for clinical diagnosis and epitranscriptomic research.