Label-Free Imaging of Flap Endonuclease 1 in Living Cells by Assembling Original and Multifunctional Nanoprobe

A fluorescence biosensor with a dual-function DNA probe targeting the activated estrogen receptor for estrogenic activity evaluation

Rapid screening and evaluation of endocrine disruption chemicals including environmental estrogens (EEs) is crucial for environmental safety and public health. Conventional methods such as animal tests and cell assays are costly, time consuming, and hardly reproducible. In this work, a fluorescence biosensor mimicking the molecular interactions in the estrogen receptor (ER) signaling pathway was developed for the rapid evaluation of estrogenic activity of environmental chemicals. The key element of the biosensor is a dual-function DNA probe composed of an ER binding sequence and a dye-binding sequence. The ER binding sequence is part of the estrogen response element in the ER signaling pathway and used to bind the activated ER. The dye-binding sequence consists of six thymine bases which the OliGreen fluorescent dye binds to selectively and thus labels non-covalently. In the presence of an estrogenic chemical, ER is activated and then complexed with the DNA, leading to a reduction in the fluorescence anisotropy of OliGreen. Detection of estradiol produced a dose-response curve with an EC50 of 3 nM and lower limit of 0.5 nM, whereas a known ER antagonist did not show any response. Five emerging contaminants including resorcinol bis(diphenyl) phosphate (RDP), triphenyl phosphate (TPHP), tris (2-chloroisopropyl) phosphate (TCIPP), perfluoro-nonenoxybenzene sulfonate (OBS) and perfluorooctanoic acid (PFOA) were evaluated by the biosensor, and the results were consistent with those of the cell assays. Detection of RDP, TPHP and OBS in spiked river water samples resulted in recovery rates of 103%, 93%, and 98%, respectively. The biosensor detection is significantly faster, more robust and easier to carry out than the cell assays, and may provide a new high throughput technique for the screening of estrogenic chemicals and environmental contaminants.

Application and development of biosensing strategies for the analysis of the activity of the tumour-associated enzyme FEN1

As a core genetic biomolecule in ecosystems, the metabolic processes of DNA, particularly DNA replication and damage repair, are regulated by Flap endonuclease 1 (FEN1). Abnormal expression and dysfunction of FEN1 may lead to genomic instability, which can induce a variety of chromosome-associated disorders, including tumours. FEN1 has emerged as a prominent tumour marker. It is crucial to precisely assess FEN1 activity and identify its associated inhibitors for both experimental research and clinical applications. However, traditional detection methods are laborious and time-consuming. Despite the increasing number of studies on biosensing strategies for detecting low-abundance FEN1 owing to the continuous innovation of new technologies and materials, they have not been systematically organised and evaluated in the public domain. Herein, we review research progress in biosensing strategies based on FEN1 detection, which are classified into nanotechnology-mediated strategies, amplification strategies, and their combinations. In addition, we summarise the existing challenges of the new methods and present a perspective on the future direction of the FEN1 analysis.

Ultrasensitive Detection of FEN1 Activity for Cancer Diagnosis Using a CRISPR/Cas13a-Based Triple Cascade Amplification System

Flap endonuclease 1 (FEN1) is closely associated with tumor progression and proliferation, making it a promising biomarker for cancer diagnosis. However, developing a sensitive, reliable, and user-friendly method for quantitative FEN1 detection remains technically challenging. In this study, an ultrasensitive FEN1 biosensor is established using a target-induced cleavage-ligation-transcription-activation cascade strategy (LTACas13a) to enhance the cleavage ability of CRISPR/Cas13a. The LTACas13a method has shown excellent performance in screening FEN1 inhibitors and detecting endogenous FEN1 activity in living cells, as well as in clinical biological samples such as human serum and tissue samples. Additionally, using a universal dumbbell probe derived from FEN1, a multiplex LTACas13a strategy is developed for detecting various DNA glycosylases, including formamidopyrimidine DNA glycosylase, uracil DNA glycosylase, and human alkyl adenine DNA glycosylase. This straightforward approach provides a reliable and effective diagnostic tool for early-stage cancer detection and offers significant opportunities for FEN1 biosensing and related drug discovery.

Construction of a Multiple Cyclic Ligation-Promoted Exponential Recombinase Polymerase Amplification Platform for Sensitive and Simultaneous Monitoring of Cancer Biomarkers Fpg and FEN1

Formamidopyrimidine DNA glycosylase (Fpg) and flap endonuclease 1 (FEN1) are essential to sustaining genomic stability and integrity, while the abnormal activities of Fpg and FEN1 may lead to various diseases and cancers. The development of simple methods for simultaneously monitoring Fpg and FEN1 is highly desirable. Herein, we construct a multiple cyclic ligation-promoted exponential recombinase polymerase amplification (RPA) platform for sensitive and simultaneous monitoring of Fpg and FEN1 in cells and clinical tissues. We designed two programmable substrate probes with 8-oxo-7,8-dihydroguanine (8-oxoG) damage sites and 5' flaps that can be identified/cleaved by Fpg and FEN1 to produce nicking sites. The juxtaposition of the cleavage sites is ligated by DNA ligase to form intact double-stranded DNA (dsDNA) templates that can be amplified via RPA to produce abundant dsDNA products labeled with Cy5 and Cy3 fluorophores and biotin, respectively. The resultant dsDNA can be captured by magnetic beads and subsequently disassembled into dispersed Cy3 and Cy5 molecules upon heat treatment, generating significant fluorescence signals. This assay exhibits a limit of detection of 1.12 × 10-10 U μL-1 for Fpg and 1.66 × 10-9 U μL-1 for FEN1, and it can be used for the analysis of enzymatic kinetic parameters, screening of inhibitors, and simultaneous monitoring of Fpg and FEN1 in a single cell and in clinic tissue samples. Moreover, the proposed strategy can be applied to monitor other DNA repair proteins by merely changing the recognition sites of dsDNA substrate probes, providing a promising platform for clinical diagnosis, biomedical research, and drug discovery.

A simple "mix-and-detection" method based on template-free amplification for sensitive measurement of human cellular FEN1

Flap endonuclease 1 (FEN1) is a structure-specific nuclease that can specially identify and cleave 5' flap of branched duplex DNA, and it plays a critical role in DNA metabolic pathways and human diseases. Herein, we propose a simple "mix-and-detection" strategy for sensitive measurement of human cellular FEN1 on basis of template-free amplification. We design a dumbbell probe with 5' flap as a substrate of FEN1 and a NH2-labeled 3' termini to prevent nonspecific amplification. When FEN1 is present, the 5' flap is cleaved to release a free 3'-OH termini, initiating Ribonuclease HII (RNase HII)-assisted terminal deoxynucleotidyl transferase (TdT)-induced amplification for the production of a significant fluorescence signal. Due to the high exactitude of TdT-mediated extension reaction and RNase HII-induced single ribonucleotide excise, this assay shows excellent specificity and high sensitivity with a detection limit of 5.64 × 10-6 U/μL. Importantly, it can detect intracellular FEN1 activity with single-cell sensitivity under isothermal condition in a "mix-and-detection" manner, screen the FEN1 inhibitors, and even discriminate tumor cells from normal cells, offering a new platform for disease diagnosis and drug discovery.

A one-pot transcriptional assay method that detects the tumor biomarker FEN1 based on its flap cleavage activity

BACKGROUND

Detection of tumor biomarkers in body fluids is a significant advancement in cancer treatment because it allows diagnosis without invasive tissue biopsies. Nucleases have long been regarded as a potential class of biomarkers that can indicate the occurrence and progression of cancers. Among these, flap endonuclease 1 (FEN1) plays an important role in DNA replication and repair, and also overexpressed in abnormally proliferating cells such as cancer cells. FEN1 is thus considered to be a potential biomarker as well as a target for cancer therapy.

RESULTS

We developed a novel method for detecting FEN1 based on its specific endonuclease activity which incises bifurcated nucleic acids (flaps), in combination with in vitro transcription. Developed method uses a simple DNA structure (substrate DNA) carrying a short 5'-flap sequence, and a single-stranded sensor DNA encoding the Broccoli light-up aptamer. When the assay mixture was supplied with a FEN1-containing sample, the flap sequence encoding the sense sequence of T7 promoter was cleaved and released from the substrate DNA. Because the sensor DNA was designed to carry the Broccoli RNA aptamer under the antisense sequence of T7 promoter, hybridization of the excised flap onto the sensor DNA initiated the transcription of the Broccoli RNA aptamer, enabling determination of the FEN1 titer based on the fluorescence of transcribed Broccoli aptamer. By using a combination of FEN1-mediated generation of a short oligonucleotide and subsequent oligonucleotide-dependent in vitro transcription, this method could detect FEN1 in biological samples within 1 h.

SIGNIFICANCE AND NOVELTY

Developed method enables the detection of FEN1 by a simple one-pot reaction. It can detect sub-nanomolar concentrations of FEN1 within an hour, and has the potential to be used for cancer diagnosis, prognosis, and drug screening. It also enables easy identification of compounds that inhibit FEN1 activity and is thus a versatile platform for screening anti-cancer drugs. We anticipate that the basic principles of this assay can be applied to detect other biomolecules, such as nucleic acids.

Construction of dual exponential amplification accompanied by multi-terminal signal output method for convenient detection of tumor biomarker FEN1 activity

As an important 5'-nuclease in DNA replication and damage repair, Flap endonuclease 1 (FEN1) has been considered as a potential tumor biomarker due to its overexpression in different human cancer cells. Here, we developed a convenient fluorescent method based on dual enzymatic repairing exponential amplification accompanied by multi-terminal signal output to realize the rapid and sensitive detection of FEN1. In the presence of FEN1, the double-branched substrate could be cleaved to produce 5' flap single strand DNA (ssDNA) which subsequently was used as a primer to initiate the dual exponential amplification (EXPAR) to generate abundant ssDNAs (X' and Y'), then the ssDNAs can respectively hybridize with the 3' and 5' ends of the signal probe to form partially complementary double strands (dsDNAs). Subsequently, the signal probe on the dsDNAs could be digested under the assistance of Bst. polymerase and T7 exonuclease, as well as releasing the fluorescence signals. The method displayed high sensitivity with the detection limit of 9.7 × 10^-3 U mL^-1 (1.94 × 10^-4 U) and also exhibited good selectivity towards FEN1 under the challenge from complicated samples including extracts of normal and cancer cells. Furthermore, it was successfully applied to screen FEN1 inhibitors, holding great promise in the screening of potential drugs targeting FEN1. This sensitive, selective and convenient method could be used for FEN1 assay without the complicated nanomaterial synthesis/modification, showing great potential in FEN1- related prediction and diagnosis.

Label-free and low-background FEN1 sensing based on cleavage-induced ligation of bifunctional dumbbell DNA and in-situ signal readout

Flap endonuclease 1 (FEN1) is overexpressed in various types of human tumor cells and has been recognized as a promising biomarker for cancer diagnosis in recent years. In this work, a label-free fluorescent nanosensor for FEN1 detection was developed based on cleavage-induced ligation of bifunctional dumbbell DNA and in-situ signal readout by copper nanoparticles (CuNPs). The dumbbell DNA was rationally designed with a FEN1 cleavable 5' flap for target recognition and AT-riched stem-loop template for CuNPs formation. In the presence of FEN1, 5' overhanging DNA flap of dumbbell DNA was effectively removed to form a linkable nick site. After the ligation by T4 DNA ligase, the dumbbell DNA changed to exonuclease-resisted closed structure which enabled in-situ generation of fluorescent CuNPs that served as signal source for target quantification. The low background attributed to synergic digestion by exonucleases facilitated the highly sensitive detection of FEN1 with limit of detection of 0.007 U/mL. Additionally, the sensor was extended to the assay of FEN1 inhibitor (aurintricarboxylic acid) with reasonable results. Last but not least, the normal cells and tumor cells were distinguished unambiguously by this sensor according to the detected concentration difference of cellular FEN1, which indicates the robustness and practicability of this nanosensor.

Lighting-up aptamer transcriptional amplification for highly sensitive and label-free FEN1 detection

Specific and sensitive detection of flap endonuclease 1 (FEN1), an enzyme biomarker involved in DNA replications and several metabolic pathways, is of high values for the diagnosis of various cancers. In this work, a fluorescence strategy based on transcriptional amplification of lighting-up aptamers for label-free, low background and sensitive monitoring of FEN1 is developed. FEN1 cleaves the 5' flap of the DNA complex probe with double flaps to form a notched dsDNA, which is ligated by T4 DNA ligase to yield fully complementary dsDNA. Subsequently, T7 RNA polymerase binds the promoter region to initiate cyclic transcriptional generation of many RNA aptamers that associate with the malachite green dye to yield highly amplified fluorescence for detecting FEN1 with detection limit as low as 0.22 pM in a selective way. In addition, the method can achieve diluted serum monitoring of low concentrations of FEN1, exhibiting its potential for the diagnosis of early-stage cancers.

Controllable crRNA Self-Transcription Aided Dual-Amplified CRISPR-Cas12a Strategy for Highly Sensitive Biosensing of FEN1 Activity

A controllable crRNA self-transcription aided dual-amplified CRISPR-Cas12a strategy (termed CST-Cas12a) was developed for highly sensitive and specific biosensing of flap endonuclease 1 (FEN1), a structure-selective nuclease in eukaryotic cells. In this strategy, a branched DNA probe with a 5' overhanging flap was designed to serve as a hydrolysis substrate of FEN1. The flap cut by FEN1 was annealed with a template probe and functioned as a primer for an extension reaction to produce a double-stranded DNA (dsDNA) containing a T7 promoter and crRNA transcription template. Assisting the T7 RNA polymerase, abundant crRNA was generated and assembled with Cas12a to form a Cas12a/crRNA complex, which can be activated by a dsDNA trigger and unlock the indiscriminate fluorophore-quencher reporter cleavage. The highly efficient dual signal amplification and near-zero background enabled CST-Cas12a with extraordinarily high sensitivity. Under optimized conditions, this method allowed highly sensitive biosensing of FEN1 activity in the range of 1 × 10^-5 U μL^-1 to 5 × 10^-2 U μL^-1 with a detection limit of 5.2 × 10^-6 U μL^-1 and achieved excellent specificity for FEN1 in the presence of other interfering enzymes. The inhibitory capabilities of chemicals on FEN1 were also investigated. Further, the newly established CST-Cas12a strategy was successfully applied to FEN1 biosensing in complex biological samples, which might be a reliable biosensing platform for highly sensitive and specific detection of FEN1 activity in clinical applications.

Label-Free and Homogeneous Electrochemical Biosensor for Flap Endonuclease 1 Based on the Target-Triggered Difference in Electrostatic Interaction between Molecular Indicators and Electrode Surface

Target-induced differences in the electrostatic interactions between methylene blue (MB) and indium tin oxide (ITO) electrode surface was firstly employed to develop a homogeneous electrochemical biosensor for flap endonuclease 1 (FEN1) detection. In the absence of FEN1, the positively charged methylene blue (MB) is free in the solution and can diffuse onto the negatively charged ITO electrode surface easily, resulting in an obvious electrochemical signal. Conversely, with the presence of FEN1, a 5′-flap is cleaved from the well-designed flapped dumbbell DNA probe (FDP). The remained DNA fragment forms a closed dumbbell DNA probe to trigger hyperbranched rolling circle amplification (HRCA) reaction, generating plentiful dsDNA sequences. A large amount of MB could be inserted into the produced dsDNA sequences to form MB-dsDNA complexes, which contain a large number of negative charges. Due to the strong electrostatic repulsion between MB-dsDNA complexes and the ITO electrode surface, a significant signal drop occurs. The signal change (ΔCurrent) shows a linear relationship with the logarithm of FEN1 concentration from 0.04 to 80.0 U/L with a low detection limit of 0.003 U/L (S/N = 3). This study provides a label-free and homogeneous electrochemical platform for evaluating FEN1 activity.

A highly sensitive homogeneous electrochemiluminescence biosensor for flap endonuclease 1 based on branched hybridization chain reaction amplification and ultrafiltration separation

A sensitive homogeneous electrochemiluminescence (ECL) biosensor for flap endonuclease 1 (FEN1) detection was developed by combining highly sensitive ECL detection, high efficiency of branched hybridization chain reaction (BHCR) amplification, a convenient homogeneous strategy, and simple ultrafiltration separation. Magnetic beads were first modified with well-designed double flap DNAs containing 5'-flaps. In the presence of FEN1, the 5'-flap can be cleaved, and a large amount of single-stranded DNA can be produced, which can be separated easily from the double-flap DNA-modified beads by a magnet. Then, the cleaved 5'-flap can be used to initiate BHCR amplification to produce a large amount of long-strand dsDNA. Ru(phen)₃²⁺ can insert dsDNA to form Ru-dsDNAs, which can be easily separated from the main solution through ultrafiltration. The ECL signal from the separated Ru-dsDNAs has a good linear relationship with the logarithm of the FEN1 concentration ranging from 6.5 × 10^-2 ∼ 6.5 × 10³ U/L with a detection limit of 2.2 × 10^-2 U/L. The proposed biosensor was used to evaluate FEN1 activity in real samples with satisfactory results.

Recent advances in DNA walker machines and their applications coupled with signal amplification strategies: A critical review

DNA walkers, a type of dynamic nanomachines, have become the subject of burgeoning research in the field of biology. These walkers are powered by driving forces based on strand displacement reactions, protein enzyme/DNAzyme reactions and conformational transitions. With the unique properties of high directionality, flexibility and efficiency, DNA walkers move progressively and autonomously along multiple dimensional tracks, offering abundant and promising applications in biosensing, material assembly and synthesis, and early cancer diagnosis. Notably, DNA walkers identified as signal amplifiers can be combined with various amplification approaches to enhance signal transduction and amplify biosensor sensing signals. Herein, we systematically and comprehensively review the walking principles of various DNA walkers and the recent progress on multiple dimensional tracks by presenting representative examples and an insightful discussion. We also summarized and categorized the diverse signal amplification strategies with which DNA walkers have coupled. Finally, we outline the challenges and future trends of DNA walker machines in emerging analytical fields.

Dual-Mode FEN1 Activity Detection Based on Nt.BstNBI-Induced Tandem Signal Amplification

Flap endonuclease 1 (FEN1) is a structure-specific nuclease that cleaves the 5' single-stranded protrusion (also known as 5' flap) during Okazaki fragment processing. It is overexpressed in various types of human cancer cells and has been considered as an important biomarker for cancer diagnosis. However, conventional methods for FEN1 assay usually suffer from complicated platform and laborious procedures with a limited sensitivity. Here, we developed a dual-signal method for sensitive detection of FEN1 on the basis of duplex-specific nuclease actuated cyclic enzymatic repairing-mediated signal amplification. Once the 5' flap of the double-flap DNA substrate was cleaved by target FEN1, the cleaved 5' flap initiated strand-displacement amplification to produce plenty of G-rich DNA (G) sequences. These G sequences that self-assembled into G-quadruplexes in the presence of hemin revealed horseradish-peroxidase-like catalytic activities as well as fluorescence enhancement of thioflavin T. The UV-vis signal showed a good linear relationship with the logarithm of FEN1 activity ranging from 0.03 to 1.5 U with a detection limit of 0.01 U. The fluorescence signal correlated linearly with the logarithm of FEN1 activity ranging from 0.001 to 1.5 U with a detection limit of 0.75 mU. In addition, FEN1 can be visualized not only by colorimetry but also by fluorescence (under ice-water mixture conditions). This reliable, accurate, and convenient method would be a potential powerful tool in point-of-care testing applications and therapeutic response assessment.

An OliGreen-responsive fluorescence sensor for sensitive detection of organophosphorus pesticide based on its specific selectivity towards T-Hg2+-T DNA structure

In this paper, it was found that OliGreen emitted much stronger fluorescence in rigid T-Hg²⁺-T DNA structure than that in the presence of poly T. Thus, an OliGreen-responsive label-free fluorescent sensor was proposed for sensitive detection of organophosphorus pesticides (OPs) by constructing T-Hg²⁺-T DNA structure. OliGreen emits strong fluorescence in T-Hg²⁺-T structures. The rigid DNA structure of T-Hg²⁺-T is prone to be destroyed by thiocholine (TCh) that hydrolyzed by acetylcholinesterase (AChE) because of the high affinity of TCh with Hg²⁺. As a result, T-Hg²⁺-T DNA structure broke down and the fluorescence intensity of OliGreen decreased greatly. With the inhibition of AChE by OPs, fluorescence intensity of OliGreen remained strong because of the rigid T-Hg²⁺-T DNA structure. Thus, a "turn-on" fluorescent sensor which avoids synthesis of nanomaterials and complex label procedures is proposed based on the fluorescence intensity of OliGreen. DDVP were detected with a wide linear range from 0.005 to 25.0 ng/mL and the detection limit was 2.9 pg/mL, which is more sensitive than previously reported methods.

Signal-Amplified Detection of the Tumor Biomarker FEN1 Based on Cleavage-Induced Ligation of a Dumbbell DNA Probe and Rolling Circle Amplification

Flap endonuclease 1 (FEN1), an endogenous nuclease with the ability to cleave the 5' overhang of branched dsDNA, is of significance in DNA replication and repair. The overexpression of FEN1 is common in cancer because of the ubiquitous upregulation of DNA replication; thus, FEN1 has been recognized as a potential biomarker in oncological investigations. However, few analytical methods targeting FEN1 with high sensitivity and simplicity have been developed. This work developed a signal-amplified detection of FEN1 based on the cleavage-induced ligation of a dumbbell DNA probe and rolling circle amplification (RCA). A flapped dumbbell DNA probe (FDP) was rationally designed with a FEN1 cleavable flap at the 5' end. The cleavage generated a nick site with juxtaposed 5' phosphate and 3' hydroxyl ends, which were linkable by T4 DNA ligase to form a closed dumbbell DNA probe (CDP) with a circular conformation. The CDP functioned as a template for RCA, which produced abundant DNA that could be probed using SYBR Green I. The highly sensitive detection of FEN1 with a limit of detection of 15 fM was achieved, and this method showed high specificity, which enabled the quantification of FEN1 in real samples. The inhibitory effects of chemicals on FEN1 were also evaluated. This study represents the first attempt to develop an FEN1 assay that involves signal amplification, and the novel biosensor method enriches the tools for FEN1-based diagnostics.