A novel nanoparticle surface-constrained CRISPR-Cas12a 3D DNA walker-like nanomachines for sensitive and stable miRNAs detection

One-pot synthesized three-way junction based multiple strand displacement amplification for sensitive assay of H5N1 DNA

The rapid and sensitive detection of H5N1, a highly pathogenic avian influenza virus, is crucial for controlling its spread and minimizing its impact on public health. In this study, we developed a novel biosensor based on strand displacement amplification (SDA) coupled with CRISPR/Cas12a for highly sensitive detection of H5N1 DNA. The biosensor utilizes a combination of a three-way junction structure, composed of three hairpins (H1, H2, H3), to initiate amplification through SDA, resulting in the production of numerous activators. These activators then trigger CRISPR/Cas12a's collateral cleavage activity, which generates a detectable fluorescence signal. The biosensor demonstrated a linear detection range from 100 fM to 800 pM, with a detection limit as low as 72.87 fM. The optimized biosensor exhibited excellent sensitivity, high specificity, and a broad dynamic range, making it a promising tool for the early detection of H5N1 DNA in complex biological samples. Additionally, the use of CRISPR/Cas12a's trans-cleavage activity significantly improved signal amplification and specificity, allowing for more reliable detection compared to traditional methods. The results highlight the advantages of the integrated SDA and CRISPR/Cas12a approach, which addresses the limitations of conventional detection methods, such as low sensitivity, lengthy analysis times, and high costs. The biosensor's ability to perform well in complex sample matrices demonstrates its potential for point-of-care diagnostics, especially in resource-limited settings. Future applications of this technology could extend to the detection of other pathogens, offering a versatile and adaptable platform for disease surveillance and management.

Magnetic Assisted DNA Logic Gate Nanomachine Based on CRISPR/Cas12a for Recognition of Dual miRNAs

The anomalous expression of microRNA poses a serious threat to human life and health safety, and serves as an important biomarker for cancer detection. In this study, a novel magnetic-assisted DNA logic gate nanomachine triggered by miRNA-21 and miRNA-155 was designed based on the trans-cleavage activity of CRISPR/Cas12a activated by a split DNA activator, using only a single crRNA and signal probe, which simplified the detection procedure and complex nucleic acid amplification. The presence of target molecules, miRNA-21 and miRNA-155, can stimulate the DNA walker machine assembled on magnetic beads, which releases activator under the action of DNAzyme. Then the trans-cleavage activity of CRISPR/Cas12a is initiated and the system signal significantly increases. Based on this, an AND logic gate nanomachine was constructed for simultaneous analysis of miRNA-21 and miRNA-155. The detection limits of miRNA-21 and miRNA-15 were 9.00 pM and 42.00 pM, respectively, and this method was successfully applied to miRNA analysis in cell samples. This nanomachine combined the DNA walker with DNA logic circuit and CRISPR/Cas12a system, providing a new approach for simultaneous detection of multiple targets and further expanding the application of gene editing in the analysis and sensing of multiple target substances.

Multiple gRNAs-assisted CRISPR/Cas12a-based portable aptasensor enabling glucometer readout for amplification-free and quantitative detection of malathion

BACKGROUND

The threat of toxic malathion residues to human health has always been a serious food safety issue. The CRISPR/Cas system represents an innovative detection technology for pesticide residues, but its application to malathion detection has not been reported yet. In addition, the multiple-guide RNA (gRNA) powered-CRISPR/Cas biosensor has the advantages of being fast, sensitive and does not require pre-amplification. However, the reported multiple-gRNA CRISPR/Cas-based biosensors are largely only used for the detection of nucleic acid targets, and there are still certain challenges in detecting non-nucleic acid targets.

RESULTS

In this work, a multiplex-gRNA-assisted CRISPR/Cas12a-based portable aptasensor (MgCPA) is developed for amplification-free and quantitative detection of malathion using a glucometer. When target malathion is present in the MgCPA strategy, it specifically binds with aptamer and then activates the trans-cleavage activity of the multiplex-gRNA CRISPR/Cas12a. The activated multiple Cas12a/gRNA complexes cut invertase-HP probes on the electrode surface to obtain glucose signals with glucometer assistance. Under optimal conditions, the developed MgCPA strategy achieves satisfactory portable quantitative and sensitive detection of malathion down to 300 fM (S/N = 3) without pre-amplification. Moreover, the satisfactory selectivity, high reproducibility, and good stability of the proposed strategy are also obtained. Due to its excellent and robust shelf life, our developed MgCPA strategy can be practically applied in detecting malathion in orange, apple, cabbage, and spinach samples.

SIGNIFICANCE

Amplification-free, sensitive, portable quantitative and selective detection of malathion in food samples is achieved by employing our developed MgCPA strategy. This strategy not only opens up a new path for the non-nucleic-acid target detection using amplification-free methods based on multiple-gRNA-assisted CRISPR/Cas12a, but also has broad application prospects in ensuring food safety.

CRISPR detection of cardiac tumor-associated microRNAs

As multiple imaging modalities cannot reliably diagnose cardiac tumors, the molecular approach offers alternative ways to detect rare ones. One such molecular approach is CRISPR-based diagnostics (CRISPR-Dx). CRISPR-Dx enables visual readout, portable diagnostics, and rapid and multiplex detection of nucleic acids such as microRNA (miRNA). Dysregulation of miRNA expressions has been associated with cardiac tumors such as atrial myxoma and angiosarcoma. Diverse CRISPR-Dx systems have been developed to detect miRNA in recent years. These CRISPR-Dx systems are generally classified into four classes, depending on the Cas proteins used (Cas9, Cas12, Cas13, or Cas12f). CRISPR/Cas systems are integrated with various isothermal amplifications to detect low-abundance miRNAs. Amplification-free CRISPR-Dx systems have also been recently developed to detect miRNA directly. Herein, we critically discuss the advances, pitfalls, and future perspectives for these CRISPR-Dx systems in detecting miRNA, focusing on the diagnosis and prognosis of cardiac tumors.

CRISPR/Cas12a-enhanced DNA nanomachine for multiple respiratory pathogens detection

Respiratory infection caused by pathogens is among the most prevalent health issues affecting people worldwide. Accurate and rapid screening of respiratory pathogens is crucial for selecting appropriate treatments to control epidemics. However, it is often challenged by two aspects: first, the low concentration of pathogens in the early stages of infection; second, the difficulty of analyzing multiple pathogens. Herein, we report a mass spectrometry strategy combining the CRISPR/Cas12a system with DNA nanomachines for respiratory pathogens detection. Thanks to the high sensitivity of the CRISPR/Cas12a-enhanced DNA nanomachine and the multiple analysis of elemental mass spectrometry, the proposed method was successfully applied for clinical sample analysis with a low detection limit of 28 amol, 30 amol, and 38 amol for SARS-CoV-2, influenza A virus subtype H1N1, and Mycoplasma pneumoniae, respectively.

Multipedal DNA Walker: Engineering Strategy, Biosensing Application and Future Perspectives

With the continuous development of DNA nanotechnology, DNA walkers have attracted increased attention because of their autonomous and progressive walking along predesigned tracks. Compared with the traditional DNA walkers, the emerged multipedal DNA walkers showed their special charm with sustainable walking capability, higher reaction efficiency, expanded walking region, and improved amplification capability. Consequently, multipedal DNA walkers have developed rapidly and shown potential in biosensing applications. Hence, in this review, we make a comprehensive representation of the engineering strategy of multipedal DNA walkers, which focused on the design of multiple walking strands as well as the construction of tracks and driving forces. Meanwhile, the application of multipedal DNA walkers in biosensors has been thoroughly described according to the type of biosensing signal readout. By illustrating some representative works, we also summarized the merits and challenges of multipedal DNA walker-based biosensors and offered a deep discussion of the latest progress and future.

A dual-core 3D DNA nanomachine based on DNAzyme positive feedback loop for highly sensitive MicroRNA imaging in living cells

A double 3D DNA walker nanomachine by DNAzyme self-driven positive feedback loop amplification for the detection of miRNA was constructed. This method uses two gold nanoparticles as the reaction core, and because of the spatial confinement effect the local concentration of the reactants increase the collision efficiency was greatly improved. Meanwhile, the introduction of positive feedback loop promotes the conversion efficiency. In presence of miRNA-21, a large amount of DNAzyme was released and hydrolyze the reporter probe, resulting the recovery of fluorescence signal. The linear range for miRNA-21 is 0.5-60 pmol/L, and the detection limit is 0.41 pmol/L (S/N = 3). This nanomachine has been successfully used for accurate detection of miRNA-21 expression levels in cell lysates. At the same time, it can enter cells for intracellular miRNA-21 fluorescence imaging, distinguishing tumor cells from normal cells. This combination of in vitro detection and imaging analysis of living cells can achieve the goal of jointly detecting cancer markers through multiple pathways, providing new ideas for early diagnosis and screening of diseases.

Smart Stimuli-Responsive Spherical Nucleic Acids: Cutting-Edge Platforms for Biosensing, Bioimaging, and Therapeutics

Spherical nucleic acids (SNAs) with exceptional colloidal stability, multiple modularity, and programmability are excellent candidates to address common molecular delivery-related issues. Based on this, the higher targeting accuracy and enhanced controllability of stimuli-responsive SNAs render them precise nanoplatforms with inestimable prospects for diverse biomedical applications. Therefore, tailored diagnosis and treatment with stimuli-responsive SNAs may be a robust strategy to break through the bottlenecks associated with traditional nanocarriers. Various stimuli-responsive SNAs are engineered through the incorporation of multifunctional modifications to meet biomedical demands with the development of nucleic acid functionalization. This review provides a comprehensive overview of prominent research in this area and recent advancements in the utilization of stimuli-responsive SNAs in biosensing, bioimaging, and therapeutics. For each aspect, SNA nanoplatforms that exhibit responsive behavior to both internal stimuli (including sequence, enzyme, redox reactions, and pH) and external stimuli (such as light and temperature) are highlighted. This review is expected to offer inspiration and guidance strategies for the rational design and development of stimuli-responsive SNAs in the field of biomedicine.

Strand displacement amplification triggered 3D DNA roller assisted CRISPR/Cas12a electrochemiluminescence cascaded signal amplification for sensitive detection of Ec-16S rDNA

BACKGROUND

Escherichia coli can cause gastrointestinal infection, urinary tract infection and other infectious diseases. Accurate detection of Escherichia coli 16S rDNA (Ec-16S rDNA) in clinical practice is of great significance for the identification and treatment of related diseases. At present, there are various types of sensors that can achieve accurate detection of Ec-16S rDNA. Electrochemiluminescence (ECL) has attracted considerable attention from researchers, which causes excellent performance in bioanalysis. Based on the previous research, it is significance to develop a novel, sensitive and efficient ECL biosensor.

RESULTS

In this work, an ECL biosensor for the detection of Ec-16S rDNA was constructed by integrating CRISPR/Cas12a technology with the cascade signal amplification strategy consisting of strand displacement amplification (SDA) and dual-particle three-dimensional (3D) DNA rollers. The amplification products of SDA triggered the operation of the DNA rollers, and the products generated by the DNA rollers activated CRISPR/Cas12a to cleave the signal probe, thereby realizing the change of the ECL signal. The cascade amplification strategy realized the exponential amplification of the target signal and greatly improved the sensitivity. Manganese dioxide nanoflowers (MnO2 NFs) as a co-reaction promoter effectively enhanced the ECL intensity of tin disulfide quantum dots (SnS2 QDs). A new ternary ECL system (SnS2 QDs/S2O82-/MnO2 NFs) was prepared, which made the change of ECL intensity of biosensor more significant. The proposed biosensor had a response range of 100 aM-10 nM and a detection limit of 27.29 aM (S/N = 3).

SIGNIFICANCE AND NOVELTY

Herein, the cascade signal amplification strategy formed by SDA and dual-particle 3D DNA rollers enabled the ECL biosensor to have high sensitivity and low detection limit. At the same time, the cascade signal amplification strategy was integrated with CRISPR/Cas12a to enable the biosensor to efficiently detect the target. It can provide a new idea for the detection of Ec-16S rDNA in disease diagnosis and clinical analysis.

CRISPR/Cas detection with nanodevices: moving deeper into liquid biopsy

The emerging field of liquid biopsy has garnered significant interest in precision diagnostics, offering a non-invasive and repetitive method for analyzing bodily fluids to procure real-time diagnostic data. The precision and accuracy offered by the clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein (CRISPR/Cas) technology have advanced and broadened the applications of liquid biopsy. Significantly, when combined with swiftly advancing nanotechnology, CRISPR/Cas-mediated nanodevices show vast potential in precise liquid biopsy applications. However, persistent challenges are still associated with off-target effects, and the current platforms also constrain the performance of the assays. In this review, we highlight the merits of CRISPR/Cas systems in liquid biopsy, tracing the development of CRISPR/Cas systems and their current applications in disease diagnosis particularly in liquid biopsies. We also outline ongoing efforts to design nanoscale devices with improved sensing and readout capabilities, aiming to enhance the performance of CRISPR/Cas detectors in liquid biopsy. Finally, we identify the critical obstacles hindering the widespread adoption of CRISPR/Cas liquid biopsy and explore potential solutions. This feature article presents a comprehensive overview of CRISPR/Cas-mediated liquid biopsies, emphasizing the progress in integrating nanodevices to improve specificity and sensitivity. It also sheds light on future research directions in employing nanodevices for CRISPR/Cas-based liquid biopsies in the realm of precision medicine.

A fuel-initiated DNA molecular machine for microRNA detection in serum via poly-adenine-mediated spherical nucleic acids

MicroRNAs (miRNAs) have been identified as promising disease diagnostic biomarkers. However, it is challenging to sensitively detect miRNAs, especially in complex biological environments, due to their low abundance and small size. Herein, we have developed a DNA-fueled molecular machine for sensitive detection of miRNA-22 (miR-22) in undiluted serum by combining poly-adenine-mediated spherical nucleic acids (polyA-SNAs) with a toehold mediated strand displacement reaction (TMSDR). The polyA-SNAs are constructed by the assembly of diblock DNA probes on a AuNP surface through the high binding affinity of polyA to AuNPs. The surface density of the diblock DNA probe can be controlled by tuning the length of the polyA block, and the orientation of the diblock DNA probe can adopt an upright conformation, which is beneficial to target hybridization and TMSDRs. TMSDR is an enzyme-free target recycling amplification approach. Taking advantage of polyA-mediated SNAs and TMSDR, the operation of the molecular machine based on two successive TMSDRs on polyA20-SNAs is rapid and efficient, which can significantly amplify the fluorescence response for detection of miR-22 in an undiluted complex matrix. The developed sensor can detect as low as 10 pM of target miRNA/DNA in undiluted fetal bovine serum within 30 min. The synergetic effect of polyA-mediated SNAs and TMSDR presents a potential alternative tool for the detection of biomarkers in real biological samples.

Emerging and potential use of CRISPR in human liver disease

CRISPR is a gene editing tool adapted from naturally occurring defense systems from bacteria. It is a technology that is revolutionizing the interrogation of gene functions in driving liver disease, especially through genetic screens and by facilitating animal knockout and knockin models. It is being used in models of liver disease to identify which genes are critical for liver pathology, especially in genetic liver disease, hepatitis, and in cancer initiation and progression. It holds tremendous promise in treating human diseases directly by editing DNA. It could disable gene function in the case of expression of a maladaptive protein, such as blocking transthyretin as a therapy for amyloidosis, or to correct gene defects, such as restoring the normal functions of liver enzymes fumarylacetoacetate hydrolase or alpha-1 antitrypsin. It is also being studied for treatment of hepatitis B infection. CRISPR is an exciting, evolving technology that is facilitating gene characterization and discovery in liver disease and holds the potential to treat liver diseases safely and permanently.

Chain hybridization-based CRISPR-lateral flow assay enables accurate gene visual detection

Visualized gene detection based on the CRISPR-Cas12/CRISPR-Cas13 technology and lateral flow assay device (CRISPR-LFA) has shown great potential in point-of-care testing sector. Current CRISPR-LFA methodology mainly utilizes conventional immuno-based LFA test strips, which could visualize whether the reporter probe is trans-cleaved by Cas protein, indicating the target positive detection. However, conventional CRISPR-LFA usually produces false-positive results in target negative assay. Herein, a nucleic acid Chain Hybridization-based Lateral Flow Assay platform, named CHLFA, has been developed to achieve the CRISPR-CHLFA concept. Different from the conventional CRISPR-LFA, the proposed CRISPR-CHLFA system was established based on the nucleic acid hybridization between the GNP-probe embedded in test strips and ssDNA (or ssRNA) reporter from CRISPR (LbaCas12a or LbuCas13a) reaction, which eliminated the requirement of immunoreaction in conventional immuno-based LFA. The assay realized the detection of 1-10 copy of target gene per reaction within 50 min. The CRISPR-CHLFA system achieved highly accurate visual detection of target negative samples, thus overcoming the false-positive problem that often produced in assays using conventional CRISPR-LFA. The CRISPR-CHLFA platform was further adopted for the visual detection of marker gene from SASR-CoV-2 Omicron variant and Mycobacterium tuberculosis (MTB), respectively, and 100% accuracy for the analysis of clinical specimens (45 SASR-CoV-2 specimens and 20 MTB specimens) was obtained. The proposed CRISPR-CHLFA system could provide an alternative platform for the development of POCT biosensors and can be widely adopted in accurate and visualized gene detection.

A triple-cycle amplification biosensor for colorimetric detection of mutant PIK3CAE545K based on cascade-driven DNA walker and branched hybridization strand reaction

Circulating tumor DNA (ctDNA) is an ideal candidate for liquid biopsy biomarkers. Therefore, detecting a low abundance of ctDNA is essential for early cancer diagnosis. Here, we developed a novel triple circulation amplification system integrating entropy and enzyme cascade-driven three-dimensional (3D) DNA walker and branched hybridization strand reaction (B-HCR) for ultrasensitive detection of breast cancer-related ctDNA. In this study, the 3D DNA walker was constructed by inner track probes (NH) and complex S on a microsphere. Once the DNA walker was triggered by the target, the strand replacement reaction ran first and kept circulating to rapidly displace the DNA walker containing 8-17 DNAzyme. Secondly, the DNA walker could repeatedly cleave NH autonomously along the inner track, generating numerous initiators, and then promoting B-HCR to activate the third cycle. Subsequently, the split G-rich fragments were brought in close to form the G-quadruplex/hemin DNAzyme by adding hemin, with the addition of H₂O₂ and ABTS, the target could be observed. Benefiting from triplex cycles, the PIK3CA^E545K mutation detection possesses a good linear range from 1-10³ fM, and the limit of detection was 0.65 fM. Due to the low cost and high sensitivity, the proposed strategy has great potential in early diagnosis of breast cancer.