Department of Pharmacology, School of Medicine , University of North Carolina at Chapel Hill , Chapel Hill , North Carolina 27599 , United States.
Center for Integrative Chemical Biology and Drug Discovery, School of Pharmacy , University of North Carolina at Chapel Hill , Chapel Hill , North Carolina 27599 , United States.
J Am Chem Soc. 2019 May 8;141(18):7275-7282. doi: 10.1021/jacs.8b09841. Epub 2019 Apr 23.
Dyes with environment-sensitive fluorescence have proven useful to study the spatiotemporal dynamics of protein activity in living cells. When attached to proteins, their fluorescence can reflect protein conformational changes, post-translational modifications, or protein interactions. However, the utility of such dye-protein conjugates has been limited because it is difficult to load them into cells. They usually must be introduced using techniques that perturb cell physiology, limit throughput, or generate fluorescent vesicles (e.g., electroporation, microinjection, or membrane transduction peptides). Here we circumvent these problems by modifying a proven, environment-sensitive biosensor fluorophore so that it can pass through cell membranes without staining intracellular compartments and can be attached to proteins within living cells using unnatural amino acid (UAA) mutagenesis. Reactive groups were incorporated for attachment to UAAs or small molecules (mero166, azide; mero167, alkyne; mero76, carboxylic acid). These dyes are bright and fluoresce at long wavelengths (reaching ε = 100 000 M cm, ϕ = 0.24, with excitation 565 nm and emission 594 nm). The utility of mero166 was demonstrated by in-cell labeling of a UAA to generate a biosensor for the small GTPase Cdc42. In addition, conjugation of mero166 to a small molecule produced a membrane-permeable probe that reported the localization of the DNA methyltransferase G9a in cells. This approach provides a strategy to access biosensors for many targets and to more practically harness the varied environmental sensitivities of synthetic dyes.
环境敏感性荧光染料已被证明可用于研究活细胞中蛋白质活性的时空动力学。当与蛋白质结合时,它们的荧光可以反映蛋白质构象变化、翻译后修饰或蛋白质相互作用。然而,由于难以将它们加载到细胞中,此类染料-蛋白质缀合物的实用性受到限制。它们通常必须使用会干扰细胞生理学、限制通量或产生荧光囊泡的技术(例如电穿孔、显微注射或膜转导肽)来引入。在这里,我们通过修饰一种经过验证的、对环境敏感的生物传感器荧光团来避免这些问题,使其能够在不染色细胞内隔室的情况下穿过细胞膜,并可通过非天然氨基酸 (UAA) 诱变将其附着在活细胞内的蛋白质上。引入了反应基团以与 UAAs 或小分子(mero166,叠氮化物;mero167,炔烃;mero76,羧酸)连接。这些染料明亮且在长波长下荧光(达到 ε = 100 000 M cm,ϕ = 0.24,激发 565nm,发射 594nm)。通过将 mero166 与 UAA 连接以生成用于小 GTPase Cdc42 的生物传感器,证明了 mero166 的用途。此外,mero166 与小分子的缀合产生了一种可渗透膜的探针,可报告 DNA 甲基转移酶 G9a 在细胞中的定位。这种方法为许多目标的生物传感器提供了一种策略,并更实际地利用了合成染料的各种环境敏感性。
