Engineering Anti-CRISPR Proteins to Create CRISPR-Cas Protein Switches for Activatable Genome Editing and Viral Protease Detection.

Proteins capable of switching between distinct active states in response to biochemical cues are ideal for sensing and controlling biological processes. Activatable CRISPR-Cas systems are significant in precise genetic manipulation and sensitive molecular diagnostics, yet directly controlling Cas protein function remains challenging. Herein, we explore anti-CRISPR (Acr) proteins as modules to create synthetic Cas protein switches (CasPSs) based on computational chemistry-directed rational protein interface engineering. Guided by molecular fingerprint analysis, electrostatic potential mapping, and binding free energy calculations, we rationally engineer the molecular interaction interface between Cas12a and its cognate Acr proteins (AcrVA4 and AcrVA5) to generate a series of orthogonal protease-responsive CasPSs. These CasPSs enable the conversion of specific proteolytic events into activation of Cas12a function with high switching ratios (up to 34.3-fold). These advancements enable specific proteolysis-inducible genome editing in mammalian cells and sensitive detection of viral protease activities during virus infection. This work provides a promising strategy for developing CRISPR-Cas tools for controllable gene manipulation and regulation and clinical diagnostics.

Programmable Proteolysis-Activated Transcription for Highly Sensitive Ratiometric Electrochemical Detection of Viral Protease.

Viral proteases play a crucial role in viral infection and are regarded as promising targets for antiviral drug development. Consequently, biosensing methods that target viral proteases have contributed to the study of virus-related diseases. This work presents a ratiometric electrochemical sensor that enables highly sensitive detection of viral proteases through the integration of target proteolysis-activated in vitro transcription and the DNA-functionalized electrochemical interface. In particular, each viral protease-mediated proteolysis triggers the transcription of multiple RNA outputs, leading to amplified ratiometric signals on the electrochemical interface. Using the NS3/4A protease of the hepatitis C virus as a model, this method achieves robust and specific NS3/4A protease sensing with sub-femtomolar sensitivity. The feasibility of this sensor was demonstrated by monitoring NS3/4A protease activities in virus-infected cell samples with varying viral loads and post-infection times. This study provides a new approach to analyzing viral proteases and holds the potential for developing direct-acting antivirals and novel therapies for viral infections.

Collagen Anchoring Protein-Nucleic Acid Chimeric Probe for In Situ In Vivo Mapping of a Tumor-Specific Protease.

In situ analysis of biomarkers in the tumor microenvironment (TME) is important to reveal their potential roles in tumor progression and early diagnosis of tumors but remains a challenge. In this work, a bottom-up modular assembly strategy was proposed for a multifunctional protein-nucleic chimeric probe (PNCP) for in situ mapping of cancer-specific proteases. PNCP, containing a collagen anchoring module and a target proteolysis-responsive isothermal amplification sensor module, can be anchored in the collagen-rich TME and respond to the target protease in situ and generate amplified signals through rolling cycle amplification of tandem fluorescent RNAs. Taking matrix metalloproteinase 2 (MMP-2), a tumor-associated protease, as the model, the feasibility of PNCP was demonstrated for the in situ detection of MMP-2 activity in 3D tumor spheroids. Moreover, in situ in vivo mapping of MMP-2 activity was also achieved in a metastatic solid tumor model with high sensitivity, providing a useful tool for evaluating tumor metastasis and distinguishing highly aggressive forms of tumors.

Visualization of Deep Tissue G-quadruplexes with a Novel Large Stokes-Shifted Red Fluorescent Benzothiazole Derivative.

G-quadruplex (G4) is a noncanonical nucleic acid secondary structure that has implications for various physiological and pathological processes and is thus essential to exploring new approaches to G4 detection in live cells. However, the deficiency of molecular imaging tools makes it challenging to visualize the G4 in ex vivo tissue samples. In this study, we established a G4 probe design strategy and presented a red fluorescent benzothiazole derivative, ThT-NA, to detect and image G4 structures in living cells and tissue samples. By enhancing the electron-donating group of thioflavin T (ThT) and optimizing molecular structure, ThT-NA shows excellent photophysical properties, including red emission (610 nm), a large Stokes shift (>100 nm), high sensitivity selectivity toward G4s (1600-fold fluorescence turn-on ratio) and robust two-photon fluorescence emission. Therefore, these features enable ThT-NA to reveal the endogenous RNA G4 distribution in living cells and differentiate the cell cycle by monitoring the changes of RNA G4 folding. Significantly, to the best of our knowledge, ThT-NA is the first benzothiazole-derived G4 probe that has been developed for imaging G4s in ex vivo cancer tissue samples by two-photon microscopy techniques.

Kinetics Accelerated CRISPR-Cas12a Enabling Live-Cell Monitoring of Mn2+ Homeostasis.

The CRISPR/Cas12a system has been repurposed as a versatile nuclei acid bio-imaging tool, but its utility in sensing non-nucleic acid analytes in living cells has been less exploited. Herein, we demonstrated the ability of Mn2+ to accelerate cleavage kinetics of Cas12a and deployed for live-cell Mn2+ sensing by leveraging the accelerated trans-cleavage for signal reporting. In this work, we found that Mn2+ could significantly boost both the cis-cleavage and trans-cleavage activities of Cas12a. On the basis of this phenomenon, we harnessed CRISPR-Cas12a as a direct sensing system for Mn2+, which achieved robust Mn2+ detection in the concentration range of 0.5-700 µM within 15 min in complex biological samples. Furthermore, we also demonstrated the versatility of this system to sense Mn2+ in the cytoplasm of living cells. With the usage of a conditional guide RNA, this Cas12a-based sensing method was applied to study the cytotoxicity of Mn2+ in living nerve cells, offering a valuable tool to reveal the cellular response of nerve cells to Mn2+ disorder and homeostasis.

Modular Combination of Proteolysis-Responsive Transcription and Spherical Nucleic Acids for Smartphone-Based Colorimetric Detection of Protease Biomarkers.

Sensitive and facile detection of biomarkers is essential for early diagnosis and treatment of diseases. To this end, we here proposed a colorimetric protease assay by the modular combination of proteolysis-responsive transcription and spherical nucleic acids (SNAs). In this assay, target protease-mediated proteolysis triggers the synthesis of RNAs by in vitro transcription, which subsequently results in the aggregation of SNAs with remarkable redshifts in the wavelength of surface plasmon resonance-related absorption. As a proof of concept, this assay achieved the sensitive and specific detection of matrix metalloprotease-2 (MMP-2) with a limit of detection of 3.3 pM. Moreover, the applicability of this colorimetric assay can be expanded to other protease biomarkers (e.g., thrombin and hepatitis C virus NS3/4A) by tuning the target-responsive RNA polymerase module. Furthermore, by the immobilization of SNAs on a glass fiber membrane, a test strip that enables the portable detection of target protease with a smartphone was developed. With the use of a mobile application to capture and process the colorimetric signals, this portable detection system allowed for sensitive evaluation of MMP-2 levels in biological and clinical specimens, highlighting its potential in point-of-care diagnosis of diseases.

Visual and quantitative detection of E. coli O157:H7 by coupling immunomagnetic separation and quantum dot-based paper strip.

Simple and visual quantitative detection of foodborne pathogens can effectively reduce the outbreaks of foodborne diseases. Herein, we developed a simple and sensitive quantum dot (QD)-based paper device for visual and quantitative detection of Escherichia coli (E. coli) O157:H7 based on immunomagnetic separation and nanoparticle dissolution-triggered signal amplification. In this study, E. coli O157:H7 was magnetically separated and labeled with silver nanoparticles (AgNPs), and the AgNP labels can be converted into millions of Ag ions, which subsequently quench the fluorescence of QDs in the paper strip, which along with the readout can be visualized and quantified by the change in length of fluorescent quenched band. Owing to the high capture efficiency and effective signal amplification, as low as 500 cfu mL-1 of E. coli O157:H7 could be easily detected by naked eyes. Furthermore, this novel platform was successfully applied to detect E. coli O157:H7 in spiked milk samples with good accuracy, indicating its potential in the detection of foodborne pathogens in real samples.

Chimeric Peptides Self-Assembling on Titanium Carbide MXenes as Biosensing Interfaces for Activity Assay of Post-translational Modification Enzymes.

Post-translational modifications (PTMs) refer to the chemical modifications of proteins coordinated by PTM enzymes, and they play a key role in numerous physiological and pathological processes. Herein, chimeric peptide-functionalized titanium carbide MXenes (Pep-Ti3C2) were devised for the activity assay of PTM enzymes by integration with carboxypeptidase Y (CPY)-mediated peptide cleavage. The Pep-Ti3C2 is fabricated by self-assembly of chimeric peptide probes on the surface of phospholipid-coated Ti3C2 MXenes and works as the fluorescent nanoprobe for the sensing of PTM enzymes. In the presence of a target PTM enzyme, the modification groups in the peptide probes are removed along with the digestion of the peptides by CPY, thereby leading to the release of labeled fluorophores. Consequently, fluorescent analysis of PTM enzymes, including deacetylase sirtuin-1 and protein phosphatase 2C at low-nanomolar concentrations was achieved. Furthermore, the versatility of the nanoprobes was also demonstrated in simultaneous profiling of the activities of the two PTM enzymes in different cells, as well as in evaluation of the inhibition on PTMs by small molecules in complicated biological samples. Therefore, this work deploys peptide-functionalized MXenes as a generic biosensing interface for the activity assay of PTM enzymes, providing a useful tool for biochemical research and clinical diagnosis.

Fluorometric and Colorimetric Dual-Readout Assay for Histone Demethylase Activity Based on Formaldehyde Inhibition of Ag+-Triggered Oxidation of O-Phenylenediamine.

Histone demethylases (HDMs) are vital players in epigenetic regulation and important targets in cancer treatment, but effective molecular tools for analyzing HDMs activity are still limited. Interestingly, we found that the process of Ag+-triggered oxidation of O-phenylenediamine (OPD) to 2,3-diaminophenazine (OPDox) could be efficiently inhibited by formaldehyde (HCHO), with the decrease of fluorescent and colorimetric signals from OPDox. Accordingly, we developed a novel label-free fluorescent and colorimetric dual-readout assay for HDMs activity based on direct quantitation of HCHO liberated in the demethylation process. On the basis of the excellent performance of the Ag+-OPD-based method for HCHO quantitation, lysine-specific demethylase 1(LSD1) activity was not only successfully detected with a low detection limit of 0.3 nM (fluorescence) and 0.5 nM (colorimetric) but also observed by the naked eye. Moreover, the feasibility of the proposed assay was further expanded to assess the LSD1 activity in cancer cell lysate and its inhibition through a mix-and-readout procedure. This label-free, cost-effective, and highly sensitive dual-readout assay presents a valuable tool for epigenetics research and drug discovery.

Proteolysis-Responsive Rolling Circle Transcription Assay Enabling Femtomolar Sensitivity Detection of a Target Protease Biomarker.

Proteases play crucial roles in the malignant progression of tumor and thus have been regarded as biomarkers for many cancers. Although protease assays such as immunoassays and fluorogenic substrate probes have been developed, it remains challenging for them to give consideration to both sensitivity and accuracy. Here, we describe a proteolysis-responsive rolling circle transcription assay (PRCTA) for the ultrasensitive and accurate detection of protease activities by the rational integration of a protease-responsive RNA polymerase and rolling circle transcription. Taking cancer biomarker matrix metalloproteinase-2 (MMP-2) as the model, the PRCTA, which can transduce and amplify each proteolysis event catalyzed by MMP-2 into the output of multiple tandem fluorescent RNAs by in vitro transcription, is constructed for the sensitive analysis of MMP-2 activities. Such a rational integration greatly enhances the signal gain in PRCTA, and it enables the limit of detection of MMP-2 as low as 3 fM. The feasibility of PRCTA has been validated by the sensitive analysis of cellular MMP-2 activities of different cell lines with good accuracy, and the readout can be readily visualized by a fluorescence imaging system. Therefore, PRCTA has achieved the detection of target protease biomarkers with femtomolar sensitivity, exhibiting promising potential in biomedicine research and cancer diagnosis.

Dual-Product Synergistically Enhanced Colorimetric Assay for Sensitive Detection of Lipid Transferase Activity.

Lipid transferase-catalyzed protein lipidation plays critical roles in many physiological processes and it has been an increasingly attractive therapeutic target from cancer to neurodegeneration, while sensitive detection of lipid transferase activity in biological samples remains challenging. Here, we presented an AuNP-based colorimetric method with dual-product synergistically enhanced sensitivity for convenient detection of lipid transferase activity. Homo sapiens N-myristoyltransferase 1 (HsNMT1), a key lipid transferase, was selected as the model. Accordingly, positively charged substrate peptides (Pep) of HsNMT1 can induce the aggregation of AuNPs through disrupting their electrostatic repulsion, while the HsNMT1-catalyzed lipid modification generates aggregated lipidated peptides (C14-Pep) and negatively charged HS-CoA, which will eliminate the disruption and stabilize the AuNPs by the formation of Au-S bonds, respectively. Consequently, charge reversal of the biomolecules and the formation of Au-S bonds synergistically contribute to the stability of AuNPs in the presence of HsNMT1. Therefore, the HsNMT1 activity can be visually detected by the naked eye through the color change of the AuNPs originated from the change in their distance-dependent surface plasmon resonance absorptions. Here, the A520/A610 ratio can sensitively reflect the activity of HsNMT1 in the linear range of 2-75 nM with a low detection limit of 0.56 nM. Moreover, the method was successfully applied for probing the HsNMT1 activities in different cell lysates and inhibitor screening. Furthermore, given the replaceability of the substrate peptide, the proposed assay is promising for universal application to other lipid transferases and exhibits great potential in lipid transferase-targeted drug development.

Enzyme-activated anchoring of peptide probes onto plasma membranes for selectively lighting up target cells.

In a cellular microenvironment, numerous biomolecules are involved in various physiological and pathological processes. However, for the in-depth and comprehensive understanding of their roles at the molecular level, there is still a lack of detection techniques for the in situ tracking of these biomolecules in a local environment. Herein, we engineered a membrane insertion peptide (MIP) as an enzyme-activated membrane insertion peptide probe (eaMIP) that allowed the in situ tracking of the activity of target enzymes in living cells. In this strategy, the membrane insertion capacity of the MIP motif in each eaMIP was caged by appending a chemical moiety. In the presence of target enzymes, the caging moiety in each eaMIP was removed by enzymatic decaging, leading to the generation of active MIPs. The versatility of this design was demonstrated by lighting up different tumor cells with distinct fluorescence signal patterns, affording an alternative tool for clinical diagnostics, biochemical research and membrane engineering.

Chimeric DNA-Functionalized Titanium Carbide MXenes for Simultaneous Mapping of Dual Cancer Biomarkers in Living Cells.

Acquiring multilayer information on diverse biomarkers with different spatial distributions at the cellular level is crucial for monitoring the progression of cancers. Herein, a dual-signal-tagged chimeric DNA-functionalized titanium carbide MXenes nanoprobe (dcDNA-Ti3C2) that responds to biomarkers with different cellular locations from plasma membrane to cytoplasm was designed toward this end. In the presence of cancer biomarkers, including transmembrane glycoprotein mucin 1 (MUC1) and cytoplasmic microRNA-21 (miR-21), the recognition between MUC1 and its aptamer in the dcDNA-Ti3C2 probe induces the separation of TAMRA-MUC1 aptamer from Ti3C2 MXenes, thereby resulting in an increase in red fluorescence; and the hybridization of miR-21 with the hairpin probe triggers the increase of green fluorescence. As a result, dual analysis of MUC1 and miR-21 at low-nanomolar concentrations in vitro, as well as in situ simultaneous imaging of the biomarkers within MCF-7 breast cancer cells, was achieved. The feasibility of the nanoprobe was further demonstrated by monitoring the expression changes of both the biomarkers in cancer cells under different inhibitor combinations. Therefore, this strategy allows us to acquire the expression levels and spatial distributions of different biomarkers in living cells, providing a helpful tool for reliable diagnosis of cancers and basic understanding their progression.

Functional Titanium Carbide MXenes-Loaded Entropy-Driven RNA Explorer for Long Noncoding RNA PCA3 Imaging in Live Cells.

The visualization of the long noncoding RNA of prostate cancer gene 3 (lncRNA PCA3), a specific biomarker for androgen receptor-positive prostate cancer, in living cells not only directly reflects the gene expression and localization but also offers better insight into its roles in the pathological processes. Here, we loaded an entropy-driven RNA explorer (EDRE) on the TAT peptide-functionalized titanium carbide MXenes (Ti3C2-TAT) for the imaging of nuclear lncRNA PCA3 in live cells. The EDRE was condensed on the Ti3C2-TAT (Ti3C2-TAT@EDRE) by electrostatic interaction. Ti3C2-TAT@EDRE enables the entering of cells and release of TAT peptides and EDRE in the cytoplasm by the glutathione (GSH)-triggered cleavage of the disulfide bonds in Ti3C2-TAT. The released EDRE is delivered into the nucleus by the nucleus-targeted guidance of TAT peptides, and initiated by the target lncRNA PCA3, subsequently leading to the continuous accumulation of fluorescence signals. Consequently, fluorescence analysis of lncRNA PCA3 at low-picomolar concentrations in vitro as well as sensitive live cell imaging of lncRNA PCA3 in the nucleus of androgen receptor-positive LNCaP prostate cancer cells were achieved, providing a versatile strategy for the monitoring of nucleic acid biomarkers in the nucleus of living cells.

Click-Type Protein-DNA Conjugation for Mn2+ Imaging in Living Cells.

A click-type protein-DNA conjugation, named as MnDDC (Mn2+-activated DCV-DNA conjunction), is presented, where DCV (rep protein of duck circovirus) and its target DNA work as the modular blocks to rapidly and effectively generate Mn2+-dependent and site-specific protein-DNA linkage. On the basis of MnDCC, a fluorescent Mn2+ biosensor composed of DCV and a molecular beacon, was developed for rapid sensing of Mn2+ within 2 min with nanomolar sensitivity. Using the proposed biosensor, not only analysis of Mn2+ in real samples (e.g., serum and food), but also wash-free fluorescent imaging of Mn2+ in extracellular environment and cytoplasm have been achieved. Moreover, the MnDDC-based sensor was proved to be a powerful tool for visualization of Mn2+ during exploration of the associated cytotoxicity in living neural cells, which is helpful to reveal the cellular responses toward the disordered homeostasis of Mn2+ in both extracellular and intracellular microenvironments.

DNA mimics of red fluorescent proteins (RFP) based on G-quadruplex-confined synthetic RFP chromophores.

Red fluorescent proteins (RFPs) have emerged as valuable biological markers for biomolecule imaging in living systems. Developing artificial fluorogenic systems that mimic RFPs remains an unmet challenge. Here, we describe the design and synthesis of six new chromophores analogous to the chromophores in RFPs. We demonstrate, for the first time, that encapsulating RFP chromophore analogues in canonical DNA G-quadruplexes (G4) can activate bright fluorescence spanning red and far-red spectral regions (Em = 583-668 nm) that nearly match the entire RFP palette. Theoretical calculations and molecular dynamics simulations reveal that DNA G4 greatly restricts radiationless deactivation of chromophores induced by a twisted intramolecular charge transfer (TICT). These DNA mimics of RFP exhibit attractive photophysical properties comparable or superior to natural RFPs, including high quantum yield, large Stokes shifts, excellent anti-photobleaching properties, and two-photon fluorescence. Moreover, these RFP chromophore analogues are a novel and distinctive type of topology-selective G4 probe specific to parallel G4 conformation. The DNA mimics of RFP have been further exploited for imaging of target proteins. Using cancer-specific cell membrane biomarkers as targets, long-term real-time monitoring in single live cell and two-photon fluorescence imaging in tissue sections have been achieved without the need for genetic coding.

Engineering of Nucleic Acids and Synthetic Cofactors as Holo Sensors for Probing Signaling Molecules in the Cellular Membrane Microenvironment.

The comprehensive understanding of the mechanisms underlying the interaction of cells with their membrane microenvironment is of great value for fundamental biological research; however, tracking biomolecules on cell surfaces with high temporal and spatial resolution remains a challenge. Herein, a modular strategy is presented for the construction of cell surface DNA-based sensors by engineering DNA motifs and synthetic cofactors. In this strategy, a stimuli-reactive organic molecule is employed as the cofactor for the DNA motif, and the self-assembly of them forms a FRET-based holo DNA-based sensor. With the use of the DNA-based sensors, the versatility of this modular strategy has been demonstrated in the ratiometric imaging of the cellular extrusion process of endogenous signaling molecules, including sulfur dioxide derivatives and nitric oxide.

Phospholipid-Tailored Titanium Carbide Nanosheets as a Novel Fluorescent Nanoprobe for Activity Assay and Imaging of Phospholipase D.

As one of the emerging inorganic graphene analogues, two-dimensional titanium carbide (Ti3C2) nanosheets have attracted extensive attention in recent years because of their remarkable structural and electronic properties. Herein, a sensitive and selective nanoprobe to fluorescently probe phospholipase D activity was developed on the basis of an ultrathin Ti3C2 nanosheets-mediated fluorescence quenching effect. Ultrathin Ti3C2 nanosheets with ∼1.3 nm in thickness were synthesized from bulk Ti3AlC2 powder by a two-step exfoliation procedure and further modified by a natural phospholipid that is doped with rhodamine B-labeled phospholipid (RhB-PL-Ti3C2). The close proximity between RhB and Ti3C2 leads to efficient fluorescence quenching (>95%) of RhB by energy transfer. Phospholipase D-catalyzed lipolysis of the phosphodiester bond in RhB-PL results in RhB moving away from the surface of Ti3C2 nanosheets and subsequent fluorescence recovery of RhB, providing a fluorescent "switch-on" assay for the phospholipase D activity. The proposed nanoprobe was successfully applied to quantitatively determine phospholipase D activity with a low limit of detection (0.10 U L-1) and to measure its inhibition. Moreover, in situ monitoring and imaging the activity of phospholipase D in living cells were achieved using this biocompatible nanoprobe. These results reveal that Ti3C2 nanosheets-based probes exhibit great potential in fluorometric assay and clinical diagnostic applications.

Cell-Surface-Anchored Ratiometric DNA Tweezer for Real-Time Monitoring of Extracellular and Apoplastic pH.

Precise and dynamic imaging of extracellular pH is one crucial yet challenging task for studying cell physiological and pathological processes. Here, we construct a DNA tweezer to dynamically monitor pH changes of cellular microenvironments. The DNA tweezer contains three key elements: a three-strand ssDNA-frame labeled with cholesterol to anchor it on the cell membrane, a pH-sensitive i-motif sequence in the middle to dynamically control the switch between the "open" and "closed" states of the DNA tweezer, and a pair of FRET fluorophores (rhodamine green and rhodamine red) on the two arms of the tweezer to reflect its state. With cholesterol, a natural component of cell membranes, as an anchoring element, the sensor exhibited high cell-membrane-insertion efficiency and low cytotoxicity. Using the i-motif as a sensing element, it can quickly and reversibly respond to extracellular pH in the pH range of 5.0-7.5 and further perform real-time imaging of cell-surface-pH changes with excellent spatial and temporal resolution. Moreover, apoplastic-pH change during the alkalization process of plant roots caused by rapid-alkalinization factor (RALF1) was directly detected by the sensor, demonstrating the potential applications of the sensor in cell biology, biomedical research, and plant-tissue engineering.

Transpeptidation-Mediated Assembly of Tripartite Split Green Fluorescent Protein for Label-Free Assay of Sortase Activity.

Transpeptidation of surface proteins catalyzed by the transpeptidase sortase plays a critical role in the infection process of Gram-positive pathogen, and probing sortase activity and screening its inhibitors are of great significance to fundamental biological research and pharmaceutical development, especially novel antivirulence drug design. Herein, we developed a novel fluorescent biosensor to detect sortase activity based on a transpeptidation-triggered assembly of tripartite split green fluorescent protein (split GFP). Peptide P1, composed the 10th ß-sheet of GFP (GFP10) and the sortase A (SrtA) recognition sequence (LPETX), and peptide P2, the 11th ß-sheet of GFP (GFP11) with oligoglycine at N-terminal, were designed and synthesized, respectively. Existence of SrtA enables P1 and P2 to ligate into one peptide, which could spontaneously bind to GFP1-9 (the 1st to 9th ß-sheets of GFP) and assemble into functional GFP. Thus, the sortase-catalyzed transpeptidation can switch on the fluorescence signal of GFP. The method was successfully applied to detect SrtA activity with a low detection limit of 0.16 nM and for its inhibition measurement. Moreover, the feasibility of the proposed assay was further expanded to detect SrtA in human blood and further Gram-positive pathogens analysis in frozen food. Our method, using tripartite split GFP as a readout, is facile, label-free, and sensitive and exhibits great potential as a promising platform for sortase detection and inhibitor screening.