Molecular reporters for CRISPR/Cas: from design principles to engineering for bioanalytical and diagnostic applications

A novel photosensitive nanoprobe combined with CRISPR/Cas12a for dual signal amplification detection of ANGPTL2

The detection of specific protein biomarkers holds significant potential for the early diagnosis of colorectal cancer (CRC). However, the accurate quantification of low-abundance proteins in serum presents a major challenge due to factors such as limited sensitivity and the complexity of the required methodologies. In this work, we established a universal CRISPR/Cas biosensing platform by integrating novel photosensitive nanoprobes (DA/PL@Cu NPs) and CRISPR/Cas12 system (DPC-Cas) for the highly sensitive, specific and user-friendly detection of angiopoietin-like protein 2 (ANGPTL2). The DA/PL@Cu NPs serve as a critical component in the transduction of protein recognition information into nucleic acid amplification events to produce Cas12a activators. The DPC-Cas biosensor integrates DA/PL@Cu NPs-assisted amplification with Cas12a self-amplification, enabling ultrasensitive detection of ANGPTL2 at concentrations as low as 20.00 pg/mL. The proposed DPC-Cas biosensor successfully detected ANGPTL2 in serum, demonstrating significant potential for the early diagnosis of CRC.

CRISPR analysis based on Pt@MOF dual-modal signal for multichannel fluorescence and visual detection of norovirus

Norovirus is a globally prevalent pathogen that causes acute viral gastroenteritis across all age groups, characterized by its high infectivity and low infectious dose. Consequently, the development of rapid, sensitive, and accurate detection technologies for norovirus presents a significant challenge. In this study, we demonstrate a combination of CRISPR-Cas-based reactions with Pt@MOF-linked immunoassay-like assays. This methodology enables both qualitative analysis and colorimetric readouts of Cas12a-mediated DNA/RNA detection at room temperature, as well as the generation of fluorescent signal readout through base deprotonation-induced Pt@MOF cleavage of a fluorogenic substrate. Furthermore, the integration of RPA amplification with noncanonical PAM-designed CRISPR significantly enhances the sensitivity and flexibility of detection, facilitating the extension of this strategy to other targets. Ultimately, the strategy was validated in spiked food samples with a 100% accuracy rate, consistent with RT-qPCR results. Collectively, this work showcases a viable approach for a dual-functional Pt@MOF-based CRISPR biosensing platform for bioanalysis and a flexible, universal strategy based on noncanonical PAM-designed gRNAs.

CIMNE-CRISPR: A novel amplification-free diagnostic for rapid early detection of African Swine Fever Virus

African Swine Fever Virus (ASFV) is a highly contagious pathogen with nearly 100% mortality in swine, causing severe global economic loss. Current detection methods rely on nucleic acid amplification, which requires specialized equipment and skilled operators, limiting accessibility in resource-constrained settings. To address these challenges, we developed the Covalently Immobilized Magnetic Nanoparticles Enhanced CRISPR (CIMNE-CRISPR) system. This amplification-free diagnostic system seamlessly combines target recognition, sequence-specific enrichment, and signal generation. This approach uses covalent immobilization of CRISPR-LbCas12a-crRNA complexes on Fe3O4@SiO2 core-shell magnetic nanoparticles, which improves enzyme specificity and robustness over traditional adsorption. The CIMNE-CRISPR assay reached a limit of detection (LOD) of 8.1 × 104 copies/μL and a limit of quantification (LOQ) of 4.2 × 105 copies/μL, with a dynamic range spanning 105 to 1010 copies/μL and a matrix factor of 100.29% in porcine plasma. It maintained great specificity and accurately detecting 105 copies/μL of ASFV DNA even with high mutant concentrations (1013 copies/μL). The method demonstrated decent reproducibility across different nanoparticle synthesis batches, with an RSD of 9.63% and recovery rates between 97% and 103%, and features rapid processing well-suited for field diagnostics. Overall, this system's cost-effectiveness, simplicity, and reliability highlight its potential to pave the way for advanced CRISPR-based diagnostics, particularly for diverse viral and bacterial targets in agricultural, environmental, and zoonotic disease contexts.

A novel label-free biosensor for myocardial ischemia biomarker detection via CRISPR/12a

Myocardial infarction (MI) is the leading cause of death worldwide. Here, we present a novel, label-free biosensor for detecting myocardial ischemia biomarkers via CRISPR/Cas12a. This system utilizes the unique properties of CRISPR/Cas12a and G-quadruplex-ThT-based biosensors, enabling sensitive and specific detection of ATP, a crucial biomarker in cardiovascular diseases, at concentrations as low as 23 nM. Our method demonstrates substantial improvements over traditional ATP detection techniques, such as high-performance liquid chromatography and enzymatic assays, which often require complex sample preparation methods and costly equipment. The feasibility of the biosensor was further demonstrated in various models, including heart failure in mice and hypoxic conditions in cardiomyocytes. This successfully showcased its ability to function as a practical tool for diagnosing and monitoring diseases characterized by ATP dysregulation, highlighting its effectiveness in real-world clinical scenarios. This biosensor is notable for its rapid response, ease of use, and potential for integration into point-of-care diagnostics. These features offer significant advantages for the early diagnosis and management of ischemic heart disease and other conditions where ATP serves as a key metabolic biomarker. This technology also offers significant potential for early diagnosis and monitoring of myocardial ischemia and cardiovascular diagnostics. These findings underscore the biosensor's capacity for real-time ATP monitoring, offering crucial insights into mitochondrial function and disease progression, particularly in cardiovascular and inflammatory diseases.

FRETting about CRISPR-Cas Assays: Dual-Channel Reporting Lowers Detection Limits and Times-to-Result

Clustered Regularly Interspaced Short Palindromic Repeats-CRISPR-Associated Protein (CRISPR-Cas) systems have evolved several mechanisms to specifically target foreign DNA. These properties have made them attractive as biosensors. The primary drawback associated with contemporary CRISPR-Cas biosensors is their weak signaling capacity, which is typically compensated for by coupling the CRISPR-Cas systems to nucleic acid amplification. An alternative strategy to improve signaling capacity is to engineer the reporter, i.e., design new signal-generating substrates for Cas proteins. Unfortunately, due to their reliance on custom synthesis, most of these engineered reporter substrates are inaccessible to many researchers. Herein, we investigate a substrate based on a fluorescein (FAM)-tetramethylrhodamine (TAMRA) Förster resonant energy-transfer (FRET) pair that functions as a seamless "drop-in" replacement for existing reporters, without the need to change any other aspect of a CRISPR-Cas12a-based assay. The reporter is readily available and employs FRET to produce two signals upon cleavage by Cas12a. The use of both signals in a ratiometric manner provides for improved assay performance and a decreased time-to-result for several CRISPR-Cas12a assays when compared to a traditional FAM-Black Hole Quencher (BHQ) quench-based reporter. We comprehensively characterize this reporter to better understand the reasons for the improved signaling capacity and benchmark it against the current standard CRISPR-Cas reporter. Finally, to showcase the real-world utility of the reporter, we employ it in a Recombinase Polymerase Amplification (RPA)-CRISPR-Cas12a DNA Endonuclease-Targeted CRISPR Trans Reporter (DETECTR) assay to detect Human papillomavirus in patient-derived samples.

DNA Probes for Cas12a-Based Assay with Fluorescence Anisotropy Enhanced Due to Anchors and Salts

CRISPR/Cas12a is a potent biosensing tool known for its high specificity in DNA analysis. Cas12a recognizes the target DNA and acquires nuclease activity toward single-stranded DNA (ssDNA) probes. We present a straightforward and versatile approach to transforming common Cas12a-cleavable DNA probes into enhancing tools for fluorescence anisotropy (FA) measurements. Our study involved investigating 13 ssDNA probes with linear and hairpin structures, each featuring fluorescein at one end and a rotation-slowing tool (anchor) at the other. All anchors induced FA changes compared to fluorescein, ranging from 24 to 110 mr. Significant FA increases (up to 180 mr) were obtained by adding divalent metal salts (Mg2+, Ca2+, Ba2+), which influenced the rigidity and compactness of the DNA probes. The specific Cas12a-based recognition of double-stranded DNA (dsDNA) fragments of the bacterial phytopathogen Erwinia amylovora allowed us to determine the optimal set (probe structure, anchor, concentration of divalent ion) for FA-based detection. The best sensitivity was obtained using a hairpin structure with dC10 in the loop and streptavidin located near the fluorescein at the stem in the presence of 100 mM Mg2+. The detection limit of the dsDNA target was equal to 0.8 pM, which was eight times more sensitive compared to the common fluorescence-based method. The enhancing set ensured detection of single cells of E. amylovora per reaction in an analysis based on CRISPR/Cas12a with recombinase polymerase amplification. Our approach is universal and easy to implement. Combining FA with Cas12a offers enhanced sensitivity and signal reliability and could be applied to different DNA and RNA analytes.

Strategy of functional nucleic acids-mediated isothermal amplification for detection of foodborne microbial contaminants: A review

Foodborne microbial contamination (FMC) is the leading cause of food poisoning and foodborne illness. The foodborne microbial detection methods based on isothermal amplification have high sensitivity and short detection time, and functional nucleic acids (FNAs) could extend the detectable object of isothermal amplification to mycotoxins. Therefore, the strategy of FNAs-mediated isothermal amplification has been emergingly applied in biosensors for foodborne microbial contaminants detection, making biosensors more sensitive with lower cost and less dependent on nanomaterials for signal output. Here, the mechanism of six isothermal amplification technologies and their application in detecting FMC is firstly introduced. Then the strategy of FNAs-mediated isothermal amplification is systematically discussed from perspectives of FNAs' versatility including recognition elements (Aptamer, DNAzyme), programming tools (DNA tweezer, DNA walker and CRISPR-Cas) and signal units (G-quadruplex, FNAs-based nanomaterials). Finally, challenges and prospects are presented in terms of addressing the issue of nonspecific amplification reaction, developing better FNAs-based sensing elements and eliminating food matrix effects.

CRISPR/Cas12a-based fluorescence aptasensor integrated with two-dimensional cobalt oxyhydroxide nanosheets for IFN-γ detection

Cytokine storm (CS) is a risky immune overreaction accompanied by significant elevations of pro-inflammatory cytokines including interferon-γ (IFN-γ), interleukin and tumor necrosis factor. Sensitive detection of cytokine is conducive to studying CS progress and diagnosing infectious diseases. In this study, we developed a tandem system combining aptamer, strand displacement amplification (SDA), CRISPR/Cas12a, and cobalt oxyhydroxide nanosheets (termed Apt-SCN tandem system) as a signal-amplified platform for IFN-γ detection. Owing to the stronger affinity, target IFN-γ bound specifically to the aptamer from aptamer-complementary DNA (Apt-cDNA) duplex. The cDNA released from the Apt-cDNA duplex initiated SDA, resulting in the generation of double-stranded DNA products that could activate the trans-cleavage activity of CRISPR/Cas12a. The activated CRISPR/Cas12a further cleaved FAM-labeled single-stranded DNA probe, preventing it from adhering to the cobalt oxyhydroxide nanosheets and recovering the fluorescence signal. Sensitive fluorometric analysis of IFN-γ was successfully performed with detection limit as low as 0.37 nM. Unlike traditional protein analysis methods, Apt-SCN tandem system incorporates multiple signal amplification techniques and may also be applicable for other cytokines assay. This study was the initial study to utilize SDA and CRISPR/Cas12a to detect IFN-γ, showing great potential for cytokines clinical assay and CS prevention.

Active CRISPR-Cas12a on Hydrophilic Metal-Organic Frameworks: A Nanobiocomposite with High Stability and Activity for Nucleic Acid Detection

CRISPR-Cas12a is an accurate and responsive biosensing technique, but its limited stability has restricted its widespread applications. To address this, we propose a strategy using metal-organic frameworks (MOFs) to protect Cas12a from harsh environments. After screening multiple candidate MOFs, it was found that hydrophilic MAF-7 is highly compatible with Cas12a, and the as-formed Cas12a-on-MAF-7 (COM) not only retains high enzymatic activity but also possesses excellent tolerance to heat, salt, and organic solvents. Further investigation showed that COM can serve as an analytical component for nucleic acid detection, resulting in an ultrasensitive assay for SARS-CoV-2 RNA detection with a detection limit of 1 copy. This is the first successful attempt to create an active Cas12a nanobiocomposite that functions as a biosensor without the need for shell deconstruction or enzyme release.

One-pot RPA-Cas12a assay for instant and visual detection of Burkholderia pseudomallei

Burkholderia pseudomallei is the causative agent of melioidosis, a potentially life-threatening infectious disease, and poses public health risks in endemic areas. Due to the high mortality, intrinsic antibiotic resistance, and atypical manifestations, establishing a rapid, accurate, and sensitive identification of B. pseudomallei enables earlier diagnosis, proper treatments, and better outcomes of melioidosis. Herein, we present a One-Pot CRISPR-integrated assay for Instant and Visual Detection (termed OPC-IVD) of B. pseudomallei. The integration of recombinase polymerase amplification and CRISPR-Cas12a recognition-activated trans-cleavage, achieved a true all-in-one single-tube reaction system, initiating the amplification and cleavage simultaneously, which realized a facile sample-to-answer assay. This approach could be performed with simplified DNA extraction and completed around 30 min by holding the reaction tube in the hand. The detection limit of our OPC-IVD was determined to be 2.19 copy/uL of plasmid DNA, 12.5 CFU/mL of B. pseudomallei, and 61.5 CFU/mL of bacteria in spiked blood samples, respectively. Furthermore, the introduction of internal amplification control effectively reduced the occurrence of false negatives, which was incorporated in the reaction system, and amplified simultaneously with the target and read by naked eyes. The assay exhibited 100% accuracy when evaluated in clinical isolates and samples. The streamlined workflow of our OPC-IVD of B. pseudomallei enables a field-deployable, instrument-free, and ultra-fast approach that can be utilized by non-expert personnel in the field of molecular diagnosis of melioidosis especially in under-resourced setting.

CRISPR/Cas14 provides a promising platform in facile and versatile aptasensing with improved sensitivity

CRISPR is reshaping biosensing technology due to its programmability, sensitivity, and specificity. Most current CRISPR-based biosensors are developed based on Cas12 and Cas13, while the biosensing potentials of the newly discovered Cas14 have not been fully elucidated yet. Herein, a fluorometric biosensor named HARRY (highly sensitive aptamer-regulated Cas14 R-loop for bioanalysis) was developed. The diblock ssDNA is designed to contain the activator sequence of Cas14 and the aptamer sequence of specific targets. In the absence of targets, the ssDNA activates Cas14a, then the Cas14a trans-cleavages the fluorescent reporter, causing fluorescence enhancement. In the presence of the targets, ssDNA-target assembly is formed via aptamer interaction, resulting in the inhibition of Cas14a activation. HARRY can detect ATP, Cd²⁺, histamine, aflatoxin B1, and thrombin with detection limits at the low-nanomolar level, which shows improvement compared with Cas12a-based aptasensors in sensitivity and versatility. We reasoned that the improvement is derived from the ssDNA specificity of Cas14a and found that the detection limit of HARRY is correlated to the binding affinities of aptamers. This study unlocks the potential of Cas14a in versatile aptasensing, which may inspire the development of CRISPR-based biosensors from the Cas14a branch.

A critical review of microfluidic systems for CRISPR assays

Reviewed are nucleic acid detection assays that incorporate clustered regularly interspaced short palindromic repeats (CRISPR)-based diagnostics and microfluidic devices and techniques. The review serves as a reference for researchers who wish to use CRISPR-Cas systems for diagnostics in microfluidic devices. The review is organized in sections reflecting a basic five-step workflow common to most CRISPR-based assays. These steps are analyte extraction, pre-amplification, target recognition, transduction, and detection. The systems described include custom microfluidic chips and custom (benchtop) chip control devices for automated assays steps. Also included are partition formats for digital assays and lateral flow biosensors as a readout modality. CRISPR-based, microfluidics-driven assays offer highly specific detection and are compatible with parallel, combinatorial implementation. They are highly reconfigurable, and assays are compatible with isothermal and even room temperature operation. A major drawback of these assays is the fact that reports of kinetic rates of these enzymes have been highly inconsistent (many demonstrably erroneous), and the low kinetic rate activity of these enzymes limits achievable sensitivity without pre-amplification. Further, the current state-of-the-art of CRISPR assays is such that nearly all systems rely on off-chip assays steps, particularly off-chip sample preparation.

Quantum Dot-Based Molecular Beacons for Quantitative Detection of Nucleic Acids with CRISPR/Cas(N) Nucleases

Strategies utilizing the CRISPR/Cas nucleases Cas13 and Cas12 have shown great promise in the development of highly sensitive and rapid diagnostic assays for the detection of pathogenic nucleic acids. The most common approaches utilizing fluorophore-quencher molecular beacons require strand amplification strategies or highly sensitive optical setups to overcome the limitations of the readout. Here, we demonstrate a flexible strategy for assembling highly luminescent and colorimetric quantum dot-nucleic acid hairpin (QD-HP) molecular beacons for use in CRISPR/Cas diagnostics. This strategy utilizes a chimeric peptide-peptide nucleic acid (peptide-PNA) to conjugate fluorescently labeled DNA or RNA hairpins to ZnS-coated QDs. QDs are particularly promising alternatives for molecular beacons due to their greater brightness, strong UV absorbance with large emission offset, exceptional photostability, and potential for multiplexing due to their sharp emission peaks. Using Förster resonance energy transfer (FRET), we have developed ratiometric reporters capable of pM target detection (without nucleotide amplification) for both target DNA and RNA, and we further demonstrated their capabilities for multiplexing and camera-phone detection. The flexibility of this system is imparted by the dual functionality of the QD as both a FRET donor and a central nanoscaffold for arranging nucleic acids and fluorescent acceptors on its surface. This method also provides a generalized approach that could be applied for use in other CRISPR/Cas nuclease systems.

Point-of-care CRISPR/Cas biosensing technology: A promising tool for preventing the possible COVID-19 resurgence caused by contaminated cold-chain food and packaging

The ongoing coronavirus disease 2019 (COVID-19) pandemic caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has caused great public health concern and has been a global threat due to its high transmissibility and morbidity. Although the SARS-CoV-2 transmission mainly relies on the person-to-person route through the respiratory droplets, the possible transmission through the contaminated cold-chain food and packaging to humans has raised widespread concerns. This review discussed the possibility of SARS-CoV-2 transmission via the contaminated cold-chain food and packaging by tracing the occurrence, the survival of SARS-CoV-2 in the contaminated cold-chain food and packaging, as well as the transmission and outbreaks related to the contaminated cold-chain food and packaging. Rapid, accurate, and reliable diagnostics of SARS-CoV-2 is of great importance for preventing and controlling the COVID-19 resurgence. Therefore, we summarized the recent advances on the emerging clustered regularly interspaced short palindromic repeats (CRISPR)/Cas system-based biosensing technology that is promising and powerful for preventing the possible COVID-19 resurgence caused by the contaminated cold-chain food and packaging during the COVID-19 pandemic, including CRISPR/Cas system-based biosensors and their integration with portable devices (e.g., smartphone, lateral flow assays, microfluidic chips, and nanopores). Impressively, this review not only provided an insight on the possibility of SARS-CoV-2 transmission through the food supply chain, but also proposed the future opportunities and challenges on the development of CRISPR/Cas system-based detection methods for the diagnosis of SARS-CoV-2.

The DNA-Cu nanocluster and exonuclease I integrated label-free reporting system for CRISPR/Cas12a-based SARS-CoV-2 detection with minimized background signal

CRISPR-driven biosensing is developing rapidly, but current works mostly adopt dye-labeled ssDNA as the signal reporter, which is costly and unstable. Herein, we developed a label-free and low-background reporter for...