Singlet oxygen (1O2) has a potent anticancer effect, but photosensitized generation of 1O2 is inhibited by tumor hypoxia and limited light penetration depth. Despite the potential of chemodynamic therapy (CDT) to circumvent these issues by exploration of 1O2‐producing catalysts, engineering efficient CDT agents is still a formidable challenge since most catalysts require specific pH to function and become inactivated upon chelation by glutathione (GSH). Herein, we present a catalytic microenvironment‐tailored nanoreactor (CMTN), constructed by encapsulating MoO42− catalyst and alkaline sodium carbonate within liposomes, which offers a favorable pH condition for MoO42−‐catalyzed generation of 1O2 from H2O2 and protects MoO42− from GSH chelation owing to the impermeability of liposomal lipid membrane to ions and GSH. H2O2 and 1O2 can freely cross the liposomal membrane, allowing CMTN with a built‐in NIR‐II ratiometric fluorescent 1O2 sensor to achieve monitored tumor CDT.
Facing the challenge of processes in direct coal liquefaction (DCL), it is vital to develop optimal hydrogen-donor solvent (H-donor) to dramatically moderate coal liquefaction conditions. Here, we propose an approach for rational design of optimal H-donor candidates based on density functional theory (DFT) calculations combining reverse searching algorithm. First, the mechanism of hydrogen transfer from H-donor to coal radical was investigated by using common model compounds. DFT calculations show that the concerted hydrogen transfer route promoted by coal radicals is the dominant pathway. The C−H bond dissociation enthalpies (BDEs) show strong correlation with intrinsic reaction barriers and rate constants (in log scale), which allow us to define a cheap metric for comparing the hydrogen-donation ability of different H-donors. Then the framework for rational design of H-donor candidates is established to seek molecules with low C−H BDEs based on inverse molecular design strategy. In the searching procedure, the chemical structure of parent molecule is varied by appropriate substituent from a predefined library (15 substituents). To reduce searching space, four empirical rules are proposed to guide the structural modifications. Finally, the H-donor candidates designed are validated by transition state calculations. It is confirmed that the inverse molecular design approach is effective for seeking candidate H-donors with lower reaction barriers and potentially higher rate of hydrogenation, which open a window for the rational design of optimal H-donors to improve the yields of the liquid products from coal under mild conditions.
Due to the lack of suitable chemical tools, probing the protein-specific glycation is highly challenging. Herein, we present a strategy based on glycation chemical reporter and proximity-induced FRET signal readout for visualizing protein-specific glycation in living cells. We first developed a bioorthogonal glucose analogue, 6-azido-6-deoxy-D-glucose (6AzGlc), as a novel glycation chemical reporter. Two types of DNA probes, glycation conversion probe and protein targeting probe, were designed to attach to glycation adducts and target proteins, respectively. After the protein was glycated by 6AzGlc, two DNA probes were sequentially applied to the target protein, triggering proximityinduced FRET signal readout. This strategy was successfully used to visualize glucose glycation of several proteins, including PD-L1 and integrin. More importantly, this strategy allowed us to analyze corresponding biological functions of glycated protein in the native environment.
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