磷化氢
化学
次氯酸
荧光
紧身衣
组合化学
分析物
水解
体外
细胞毒性
小分子
分子
配体(生物化学)
髓系白血病
前药
纳米颗粒
纳米技术
生物化学
选择性
药物输送
生物物理学
酶水解
树枝状大分子
有机化学
膜
小泡
葫芦素
人类免疫缺陷病毒(HIV)
作者
Fang Yuan,Xinqi Zhou,Julia L. McAfee,Benjamin M. Faulkner,Lauren Lesiak,Yuchen He,Frederik Brøndsted,Hao Fan,Eric D. Donarski,Xiaoyan Hu,B. Jill Venton,Steven Grant,Francine E. Garrett-Bakelman,Cliff I. Stains
摘要
Theranostic fluorescent platforms are capable of the selective delivery of small molecules to target cells with simultaneous optical monitoring. Such technologies promise to significantly reduce off-target effects compared with cytotoxic chemotherapy. However, small-molecule approaches are often hindered by relatively complex designs that are required to incorporate a fluorescent reporter, reactive linker, targeting ligand, and cargo into a single molecule. Herein, we provide the first direct evidence for the ability to gate the delivery of small-molecule cargos from phosphinate ester-containing Nebraska Red (NR) dyes in vitro and in living cells. This simplified system integrates the fluorescent reporter, reactive linker, and targeting ligand into one species─a phosphinate ester dye. As a proof-of-principle for delivery of drug-like molecules to cells, we developed NR-HOCl-TFMU, which responds to hypochlorous acid (HOCl), an analyte detected in acute myeloid leukemia (AML). NR-HOCl-TFMU is stable for days prior to reaction with HOCl, leading to phosphinate ester hydrolysis and production of a NIR (near-infrared, NR dye) and blue (cargo) fluorescence signal. NR dye fluorescence is directly proportional to cargo release, and NR-HOCl-TFMU is capable of selectively delivering its drug-like, small-molecule cargo to AML cells in vitro and in a localized tumor model in an HOCl-gated manner. In the long term, we envision the potential use of this technology to afford HOCl-gated delivery systems with selectivity toward HOCl-positive AML cells. More broadly, this approach provides a potentially generalizable strategy for the development of simplified theranostic agents targeted toward small-molecule analytes and enzymatic activities associated with disease.
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