Mitochondria are double-membrane-bound organelles involved mainly in supplying cellular energy, but also play roles in signaling, cell differentiation, and cell death. Mitochondria are implicated in carcinogenesis, and therefore dozens of lethal signal transduction pathways converge on these organelles. Accordingly, mitochondria provide an alternative target for cancer management. In this study, F16, a drug that targets mitochondria, and chlorambucil (CBL), which is indicated for the treatment of selected human neoplastic diseases, were covalently linked, resulting in the synthesis of a multi-mitochondrial anticancer agent, FCBL. FCBL can associate with human serum albumin (HSA) to form an HSA-FCBL nanodrug, which selectively recognizes cancer cells, but not normal cells. Systematic investigations show that FCBL partially accumulates in cancer cell mitochondria to depolarize mitochondrial membrane potential (MMP), increase reactive oxygen species (ROS), and attack mitochondrial DNA (mtDNA). With this synergistic effect on multiple mitochondrial components, the nanodrug can effectively kill cancer cells and overcome multiple drug resistance. Furthermore, based on its therapeutic window, HSAFCBL exhibits clinically significant differential cytotoxicity between normal and malignant cells. Finally, while drug dosage and drug resistance typically limit first-line mono-chemotherapy, HSA-FCBL, with its ability to compromise mitochondrial membrane integrity and damage mtDNA, is expected to overcome those limitations to become an ideal candidate for the treatment of neoplastic disease.

Herein, we report a facile method for cholesterol detection by coupling the peroxidase-like activity of polypyrrole nanoparticles (PPy NPs) and cholesterol oxidase (ChOx). ChOx can catalyze the oxidation of cholesterol to produce H2O2. Subsequently, PPy NPs, as a nanozyme, induce the reaction between H2O2 and 3,3′,5,5′-tetramethylbenzidine (TMB). Under optimal conditions, the increase is proportional to cholesterol with concentrations from 10 to 800 μM in absorbance of TMB at 652 nm. The linear range for cholesterol is 10-100 μM, with a detection limit of 3.5 μM. This reported method is successfully employed for detection of cholesterol in human serum. The recovery percentage is ranged within 96-106.9%. Furthermore, we designed a facile and simple portable assay kit using the proposed system, realizing the on-site semiquantitative and visual detection of cholesterol in human serum. The cholesterol content detected from the portable assay kit were closely matching those obtained results from solution-based assays, thereby holding great potential in clinical diagnosis and health management.
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In this work, a label-free and highly sensitive fluorescence assay was constructed for microRNA detection. Nicking-enhanced rolling circle amplification (RCA) induced by G-quadruplex formation is coupled with inner filter effect (IFE)-based quenching effects of MoS2 quantum dots (MoS2 QDs). The padlock probe contains a recognition sequence to target microRNA and an accessible nicking site. The padlock probe is cyclized upon hybridization with target microRNA. Sequentially, amplification initiates a production of a long-concatenated sequence of circular probes. Abundant G-quadruplex sequences are produced via the nicking process and then used as the trigger to initiate the next RCA. In the presence of hemin, numerous hemin/G-quadruplex DNAzymes are formed, which catalyze the oxidation of o-phenylenediamine (OPD) into the colored product 2,3-diaminophenazine, resulting in quenching of the fluorescence of MoS2 QDs. This sensing strategy enables detection of microRNA let-7a with high selectivity and a detection limit of 4.6 fM. The as-prepared sensor was applied for detecting microRNA let-7a in dilute human serum samples and achieved a satisfactory recovery rate, demonstrating its potential in clinic diagnosis of microRNA-associated disease and biochemical research.

In this work, a label-free and highly sensitive fluorescence assay was constructed for microRNA detection. Nicking-enhanced rolling circle amplification (RCA) induced by G-quadruplex formation is coupled with inner filter effect (IFE)-based quenching effects of MoS2 quantum dots (MoS2 QDs). The padlock probe contains a recognition sequence to target microRNA and an accessible nicking site. The padlock probe is cyclized upon hybridization with target microRNA. Sequentially, amplification initiates a production of a long-concatenated sequence of circular probes. Abundant G-quadruplex sequences are produced via the nicking process and then used as the trigger to initiate the next RCA. In the presence of hemin, numerous hemin/G-quadruplex DNAzymes are formed, which catalyze the oxidation of o-phenylenediamine (OPD) into the colored product 2,3-diaminophenazine, resulting in quenching of the fluorescence of MoS2 QDs. This sensing strategy enables detection of microRNA let-7a with high selectivity and a detection limit of 4.6 fM. The as-prepared sensor was applied for detecting microRNA let-7a in dilute human serum samples and achieved a satisfactory recovery rate, demonstrating its potential in clinic diagnosis of microRNA-associated disease and biochemical research. Copyright © 2020 American Chemical Society.

Artificial bases have emerged as a useful tool to expand genetic alphabets and biomedical applications of oligonucleotides. Herein, we reported that the conformation conversion enhances cellular uptake of hydrophobic 3,5-bis(trifluoromethyl)benzene (F) base double-strand-conjugated oligonucleotides. The formation of the F base double-strand caged the hydrophobic F base in the duplex strand, thus preventing F base from interacting with cells to some extent. However, upon conversion of F base double-strand-conjugated oligonucleotide to F base single-strand-conjugated oligonucleotide, F bases then were allowed to interact with cells by stronger hydrophobic interactions, followed by cellular uptake. The results were concluded as a pairing-induced cage effect of F base and have the potential for the construction of stimuli-responsive cellular uptake of functional nucleic acids.

Photodynamic therapy (PDT) is an effective and noninvasive therapeutic strategy employing light-triggered singlet oxygen (SO) and reactive oxygen species (ROS) to kill lesional cells. However, for effective in vivo delivery of PDT agent into the cancer cells, various biological obstacles including blood circulation and condense extracellular matrix (ECM) in the tumor microenvironment (TME) need to be overcome. Furthermore, the enormous challenge in design of smart drug delivery systems is meeting the difference, even contradictory required functions, in different steps of the complicated delivery process. To this end, we present that TME-activatable circular pyrochlorophyll A (PA)-aptamer-PEG (PA-Apt-CHO-PEG) nanostructures, which combine the advantages of PEG and aptamer, would be able to realize efficient in vivo imaging and PDT. Upon intravenous (i.v.) injection, PA-Apt-CHO-PEG shows "stealth-like" long circulation in blood compartments without specific recognition capacity, but once inside solid tumor, PA-Apt-CHO-PEG nanostructures are cleaved and then form PA-Apt Aptamer-drug conjugations (ApDCs) in situ, allowing deep penetration into the solid tumor and specific recognition of cancer cells, both merits, considering anticipated future clinical translation of ApDCs.

Understanding how a cell membrane protein functions on living cells remains a challenge for cell biology. Specific placement of functional molecules on specific proteins in their native environment would allow comprehensive study of proteins' dynamic functions. Existing methods cannot facilely achieve multiple modifications on specific membrane proteins. In this report, we describe an aptamer-induced, protein-specific bio-orthogonal modification technology for precise nongenetic immobilization of multiple small functional molecules on target membrane glycoproteins by combining metabolic technology and aptamer targeting. In brief, DNA probes were designed by modifying aptamers, which bind to target proteins on the surfaces of living cells pretreated with N-azidoacetylmannosamine-tetraacylated (Ac4ManNAz). The cyclooctynes tagged of DNA probes will approach the azide groups to trigger the bio-orthogonal reactions. After UV irradiation and hybridization with cDNA (complementary DNA), the aptamers can be removed, and the process can be repeated to achieve multiple modifications for multicolor imaging and cell surface nanoengineering on specific proteins.
Copyright © 2020 American Chemical Society.

Rationale: A cascade, or domino, reaction consists of two, or more, consecutive reactions such that subsequent reactions occur only if some chemical functionality has first been established in the prior step. However, while construction of predesigned and desired molecular domino reactors in a tailored manner is a valuable endeavor, it is still challenging.Methods: To address this challenge, we herein report an aptamer-based photodynamic domino reactor built through automated modular synthesis. The engineering of this reactor takes advantage of the well-established solid-phase synthesis platform to incorporate a photosensitizer into G-quadruplex/hemin DNAzyme at the molecular level.Results: As a proof of concept, our photodynamic domino reactor, termed AS1411/hemin-pyrochlorophyll A, achieves in vivo photodynamic domino reaction for efficient cancer treatment by using a high concentration of hydrogen peroxide (H2O2) in the tumor microenvironment (TME) to produce O-2, followed by consecutive generation of singlet oxygen (O-1(2)) using the pre-produced O-2. More specifically, phosphoramidite PA (pyrochlorophyll A) is coupled to aptamer AS1411 to form AS1411-PA ApDC able to simultaneously perform in vivo targeted imaging and photodynamic therapy (PDT). The insertion of hemin into the AS1411 G-quadruplex was demonstrated to alleviate tumor hypoxia by decomposition of H2O2 to produce O-2. This was followed by the generation of O-1(2) by PA to trigger cascading amplified PDT.Conclusion: Therefore, this study provides a general strategy for building an aptamer-based molecular domino reactor through automated modular synthesis. By proof of concept, we further demonstrate a novel method of achieving enhanced PDT, as well as alleviating TME hypoxia at the molecular level.