Exploiting the size exclusion effect of protein adsorption layers for electrochemical detection of microRNA: A new mechanism for design of E-DNA sensor.

The assay performance of electrochemical DNA (E-DNA) sensors is deeply influenced by the state of DNA probes immobilized on electrode. Moreover, the immobilization procedures for DNA probes are tedious and vary according to the probes and analytes. In this work, we find that the adsorption layers of bovine serum albumin (BSA) on gold electrode (AuE) possess a size exclusion effect to distinguish between single-stranded (-ss) DNA probes and the DNA fragments generated from enzymatic digestion of ssDNA probes. In detail, the BSA layers act as a gatekeeper that hinders the adsorption of a ssDNA probe on AuE but permits the DNA fragments with much smaller sizes to pass through the adsorption layers and adsorb on AuE. This finding is developed into a novel E-DNA sensor for microRNA (miRNA) detection by coupling with duplex-specific nuclease (DSN)-assisted target recycling strategy. The ssDNA probe in solution phase is enzymatically digested during the DSN-assisted target recycling process initiated by target miRNA-21, generating plenty of DNA fragments. The adsorption of these DNA fragment on BSA/AuE is permitted, which arouses electrochemical signals after binding with [Ru(NH3)6]3+ to indicate the recognition of miRNA-21. The developed E-DNA sensor possesses a wide calibration range from 0.001 to 100 pM and a low detection limit of 0.48 fM. Significantly, accurate evaluation of miRNA-21 expression levels in cancer cell lines and non-small-cell lung carcinomas (NSCLC) serum samples are successfully achieved using the developed method. This work provides a new mechanism for constructing sensitive E-DNA sensor without tedious probe immobilization procedures.

Enhanced Cancer Starvation Therapy Enabled by an Autophagy Inhibitors-Encapsulated Biomimetic ZIF-8 Nanodrug: Disrupting and Harnessing Dual Pro-Survival Autophagic Responses.

Autophagy is an important protective mechanism in maintaining or restoring cell homeostasis under physiological and pathological conditions. Nanoparticles (NPs) with certain components and morphologies can induce autophagic responses in cancer cells, providing a new perspective for establishing cancer therapy strategies. Herein, a novel nanodrug system, cell membranes-coated zeolitic imidazolate framework-8 (ZIF-8) NPs encapsulating chloroquine (CQ) and glucose oxidase (GOx) (defined as mCG@ZIF), is designed to achieve an enhanced anticancer effect with the combination of starvation therapy and an autophagy regulation strategy. It is found that ZIF-8 as a nanocarrier can induce autophagy to promote survival of cancer cells via the upstream Zn2+-stimulated mitochondrial reactive oxygen species (ROS) so that the anticancer effect is directly achieved by inhibiting this pro-survival autophagy using CQ released from mCG@ZIF under a tumor acidic microenvironment. Moreover, a cancer cell under starvation caused by GOx harnesses autophagy to maintain intracellular ATP levels and resist starvation therapy. The released CQ further inhibits the starvation-induced pro-survival autophagy and cuts off the protective pathway of cancer cells, enhancing the anticancer efficiency of GOx-based starvation therapy. Significantly, the cell membrane coating endows mCG@ZIF with excellent in vivo homotypic targeting ability. Both in vitro and in vivo results have confirmed the enhanced anticancer effect achieved by mCG@ZIF with a negligible side effect.