Selective In Situ Analysis of Mature microRNAs in Extracellular Vesicles Using a DNA Cage‐Based Thermophoretic Assay

Zhao, Shuai; Zhang, Shaohua; Hu, Huijun; Cheng, Yangchang; Zou, Kexuan; Song, Jie; Deng, Jinqi; Li, Lele; Zhang, Xiaobing; Ke, Guoliang; Sun, Jiashu

doi:10.1002/anie.202303121

Cited by 32 publications

(11 citation statements)

References 49 publications

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“…Nevertheless, most nanosensors easily degrade in serum and the pre-miRNAs (longer precursor miRNAs) containing identical sequences in EVs remained an issue to precisely recognize mature miRNAs. To meet these challenges, Sun et al [45] devised DNA cages that have considerable selectivity of size and stability in thermophoresis for the detection of mature miRNAs in EVs (Figure 6b). With this design, the sensor can detect mature miRNAs at a LOD of 2.05 fM without the interference of pre-miRNAs, which is comparable to the results of gold standard RT-PCR.…”

Section: Cell Biomarker For Differentiating Subtypes Of Cancer Based ...mentioning

confidence: 99%

“…[44] (b) The thermophoretic implemented with size-selective DNA cage for detection of mature miRNAs in EVs. [45] (c) Thermophoresis-mediated DNA computation approach for detection of receptors on EV membranes. [46] (d) Homotypic recognition-driven molecular characterization of BC exosomes (EXOs) based on using camouflaging catalytic DNA machinery.…”

Section: Cell Biomarker For Differentiating Subtypes Of Cancer Based ...mentioning

confidence: 99%

“…[46] (d) Homotypic recognition-driven molecular characterization of BC exosomes (EXOs) based on using camouflaging catalytic DNA machinery. [47] Graph copyright from reference [44][45][46][47] . associated with this.…”

Section: Cell Biomarker For Differentiating Subtypes Of Cancer Based ...mentioning

confidence: 99%

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Smart DNA sensors‐based molecular identification for cancer subtyping

Gao,

Xiong,

Gong

et al. 2023

Smart Molecules

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Molecular subtyping of cancer can greatly help to understand the development of disease and predict tumor behavior. Exploring detection methods for precise subtyping is appealing to prognosis and personalized therapy. During the past decades, DNA‐based biosensors have exhibited great potential in cancer diagnosis due to their structural programmability and functional diversity. Despite the encouraging progress that has been made, there remains an issue in improving the accuracy and sensitivity of cancer subtyping due to the complex process of disease, especially in preclinical or clinical applications. To accelerate the development of DNA sensors in the identification of cancer subtypes, in this review, we summarized their advances in molecular subtyping by analyzing the heterogeneity in categories and levels of biomarkers between cancer subtypes. The strategies toward genomic and proteomic heterogeneity in cells or on the cell surface, as well as the cancer excretions including extracellular vesicles (EVs) and microRNA (miRNAs) in serum, are summarized. Current challenges and the opportunities of DNA‐based sensors in this field are also discussed.

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Section: Cell Biomarker For Differentiating Subtypes Of Cancer Based ...mentioning

confidence: 99%

Section: Cell Biomarker For Differentiating Subtypes Of Cancer Based ...mentioning

confidence: 99%

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Smart DNA sensors‐based molecular identification for cancer subtyping

Gao,

Xiong,

Gong

et al. 2023

Smart Molecules

Self Cite

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“…Aiming to improve the sensitivity of miRNAs detection, various signal amplification systems have been developed, including nanomaterial-mediated amplification procedures [e.g., gold nanoparticles (GNPs), graphene nanosheets, and so on] − and molecular biological technique-based amplification strategies (e.g., hybridization chain reaction, strand-displacement amplification, and other DNA nanotechnology-based methods). − Among them, GNPs with excellent biocompatibility, facile preparation, and easy modification have been widely used in constructing signal amplification systems. ,,− Thermophoresis as an effective signal amplification approach utilizes the responses of particles to temperature gradient, thus inducing the motion and aggregation of particles, and finally achieving the signal amplification . Taking advantage of label-free and the capability of selectively driving suspended objects into warm or cold regions along a temperature gradient, thermophoresis has been employed for miRNA detection. , For example, Sun’s group reports a thermophoretic sensor for in situ detection of exosomal miRNAs with high accuracy, which relies on nanoflare detection of miRNAs and thermophoretic enrichment of cancer cell-derived exosomes . Therefore, we rationally designed a multifunctional gold nanoprobe for simultaneous specific distinguishment of prostate cancer CTCs and sensitive imaging of upregulated miR-21 in CTCs through thermophoresis.…”

Section: Introductionmentioning

confidence: 99%

“…46 Taking advantage of label-free and the capability of selectively driving suspended objects into warm or cold regions along a temperature gradient, thermophoresis has been employed for miRNA detection. 47,48 For example, Sun's group reports a thermophoretic sensor for in situ detection of exosomal miRNAs with high accuracy, which relies on nanoflare detection of miRNAs and thermophoretic enrichment of cancer cell-derived exosomes. 47 Therefore, we rationally designed a multifunc- In this work, a multifunctional gold nanoprobe-based thermophoretic assay was reported for simultaneously monitoring aberrant miR-21 expression in CTCs and visually discriminating CTCs, achieving the diagnosis of prostate cancer.…”

Section: ■ Introductionmentioning

confidence: 99%

Intracellular MicroRNA Imaging and Specific Discrimination of Prostate Cancer Circulating Tumor Cells Using Multifunctional Gold Nanoprobe-Based Thermophoretic Assay

Luo,

Meng,

et al. 2024

Anal. Chem.

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Circulating tumor cells (CTCs) have emerged as powerful biomarkers for diagnosis of prostate cancer. However, the effective identification and concurrently accurate imaging of CTCs for early screening of prostate cancer have been rarely explored. Herein, we reported a multifunctional gold nanoprobe-based thermophoretic assay for simultaneous specific distinguishing of prostate cancer CTCs and sensitive imaging of intracellular microRNA (miR-21), achieving the rapid and precise detection of prostate cancer. The multifunctional gold nanoprobe (GNP-DNA/Ab) was modified by two types of prostatespecific antibodies, anti-PSMA and anti-EpCAM, which could effectively recognize the targeting CTCs, and meanwhile linked double-stranded DNA for further visually imaging intracellular miR-21. Upon the specific internalization of GNP-DNA/Ab by PC-3 cells, target aberrant miR-21 could displace the signal strand to recover the fluorescence signal for sensitive detection at the single-cell level, achieving single PC-3 cell imaging benefiting from the thermophoresis-mediated signal amplification procedure. Taking advantage of the sensitive miR-21 imaging performance, GNP-DNA/Ab could be employed to discriminate the PC-3 and Jurkat cells because of the different expression levels of miR-21. Notably, PC-3 cells were efficiently recognized from white blood cells, exhibiting promising potential for the early diagnosis of prostate cancer. Furthermore, GNP-DNA/Ab possessed good biocompatibility and stability. Therefore, this work provides a great tool for aberrant miRNA-related detection and specific discrimination of CTCs, achieving the early and accurate diagnosis of prostate cancer.

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An Intelligent Redox‐Responsive DNA Circuit for Robust On‐Site Profiling of Glutathione‐MicroRNA Signaling Pathway

Wang,

Shang,

et al. 2024

Adv Funct Materials

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Synthetic biochemical circuits (e.g., DNA circuits) remain at the forefront of intracellular biosensing tasks yet are hindered by the undesired off‐site activation and the accompanying signal leakage. Herein, the study attempts to overcome this limitation by developing a simple‐yet‐powerful endogenous glutathione (GSH)‐regulating tactic that permits robust and distinguishable on‐site microRNA (miRNA) imaging under disturbed redox homeostasis. Specifically, a hierarchically activated catalytic DNA (HAD) circuit is fabricated by grafting the disulfide linkage within entropy‐driven DNA circuitry (EDC) reactants. It is exemplified that this HAD system promises the spatiotemporally selective microRNA‐21 (miR‐21) imaging in living cells and the robust differentiation of tumor cells from normal cells. The correlationship between GSH and miRNA is extensively explored in live cells, and can substantially expand the toolbox of DNA circuits for profiling intracellular biochemical processes.

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Selective In Situ Analysis of Mature microRNAs in Extracellular Vesicles Using a DNA Cage‐Based Thermophoretic Assay

Cited by 32 publications

References 49 publications

Smart DNA sensors‐based molecular identification for cancer subtyping

Smart DNA sensors‐based molecular identification for cancer subtyping

Intracellular MicroRNA Imaging and Specific Discrimination of Prostate Cancer Circulating Tumor Cells Using Multifunctional Gold Nanoprobe-Based Thermophoretic Assay

An Intelligent Redox‐Responsive DNA Circuit for Robust On‐Site Profiling of Glutathione‐MicroRNA Signaling Pathway

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