Rational design of genotyping nanodevice for HPV subtype distinction.

There are more than 200 subtypes of human papillomavirus (HPV), and high-risk HPVs are a leading cause of cervical cancer. Identifying the genotypes of HPV is significant for clinical diagnosis and cancer control. Herein, we used programmable and modified DNA as the backbone to construct fluorescent genotyping nanodevice for HPV subtype distinction. In our strategy, the dye-labeled single-stranded recognize-DNA (R-DNA) was hybridized with Black Hole Quencher (BHQ) labeled single-stranded link-DNA (L-DNA) to form three functionalized DNA (RL-DNA). Through the extension of polycytosine (poly-C) in L-DNA, three RL-DNAs can be more firmly adsorbed on graphene oxide to construct reliable genotyping nanodevice. The genotyping nanodevice had low background noise since the dual energy transfer, including Förster resonance energy transfer (FRET) from dye to BHQ and the resonance energy transfer (RET) from dye to graphene oxide. Meanwhile, the programmability of DNA allows the proposed strategy to simultaneously and selectively distinguish several HPV subtypes in solution using DNA labeled with different dyes. To demonstrate clinical potential, we show multiplexed assay of HPV subtypes in cervical scrapes, and it has been successfully applied in HPV-DNA analysis in cervical scrapes samples. The genotyping nanodevice could be developed for simultaneous and multiplex analysis of several oligonucleotides in a homogeneous solution by adjusting the recognition sequence, demonstrating its potential application in the rapid screening of multiple biomarkers.

In Situ Activation of the Receptor Aggregation for Cell Apoptosis by an AI-Au Intelligent Nanomachine via Tumor Extracellular Acidity.

Polyvalent ligand-induced cell receptor aggregation is closely related to cell behavior regulation. At present, most of the means to induce receptor aggregation rely on external stimuli such as light, heat, and magnetic fields, which may cause side effects to normal cells. How to achieve receptor aggregation on the cancer cell surface to achieve cell apoptosis selectively is still a challenge. Therefore, by taking advantage of the unique property of cancer cells' slightly acidic microenvironment, an easy-to-use apoptosis-inducing mode for the in situ activation of cell surface nucleolin clustering has been developed, which not only opened a new channel for nucleolin receptor aggregation to regulate cell function and further development but also avoided damage to normal cells, providing a new strategy for tumor treatment. Dual functional ssDNA (AS1411 aptamer and pH-responsive I-strand sequence) was modified on the surface of gold nanoparticles (AuNPs) to fabricate AI-Au intelligent nanomachines. Then, the specific binding on cancer cells and aggregation of the nucleolin receptors can be achieved via the formation of an i-Motif structure among adjacent AuNPs under the acidic microenvironment. The result showed that AI-Au nanomachines mediated nucleolin cross-linking on the cell surface, resulting in a cytotoxic effect of approximately 60%. Experiments such as calcein-AM/PI staining, nuclear dye staining, and flow cytometry demonstrated that cell apoptosis became more evident with the increase of acidity under the cell surface microenvironment. Immunofluorescence imaging further confirmed the Cyt-c/caspase-3 apoptosis pathway induced by AI-Au nanomachines. The proposed strategy used for specific cancer cell apoptosis by the in situ activation of tumor cell membrane receptor aggregation is inexpensive and simple to use, which not only provides a new means of nucleolin receptor aggregation for regulating cell function but also offers a new strategy for tumor treatment with reduced side effect to normal cells. This work is significant for comprehending the ligand-induced receptor aggregation process and can lead to the development of a promising anticancer drug.