Lanquaye Henry, Dwivedi Sushil K, Li Xinzhu, Agyemang Peter, Rickauer Grace, Arachchige Dilka Liyana, Wang Crystal, Peters Joseph, Zhen Ivy, Knighton Isabelle, Ata Athar, Werner Thomas, Liu Haiying
Department of Chemistry, Michigan Technological University, Houghton, Michigan 49931, United States.
Health Research Institute, Michigan Technological University, Houghton, Michigan 49931, United States.
ACS Appl Bio Mater. 2025 Feb 17;8(2):1707-1719. doi: 10.1021/acsabm.4c01912. Epub 2025 Feb 5.
The detection and dynamic monitoring of intracellular NAD(P)H concentrations are crucial for comprehending cellular metabolism, redox biology, and their roles in various physiological and pathological processes. To address this need, we introduce sensor , a near-infrared ratiometric fluorescent sensor for real-time, quantitative imaging of NAD(P)H fluctuations in live cells. Sensor combines a 3-quinolinium electron-deficient acceptor with a near-infrared rhodamine dye, offering high sensitivity and specificity for NAD(P)H with superior photophysical properties. In its unbound state, sensor emits strongly at 650 nm and weakly at 465 nm upon 400 nm excitation. Upon binding to NAD(P)H, it shows a fluorescence increase at 465 nm and a decrease at 650 nm, enabling accurate ratiometric measurements. Sensor also exhibits ratiometric upconversion fluorescence when excited at 800 or 810 nm, offering additional flexibility for different experimental setups. The sensor's response relies on the reduction of the 3-quinolinium acceptor by NAD(P)H, forming a 1,4-dihydroquinoline donor that enhances fluorescence at 465 nm and quenches the near-infrared emission at 650 nm through photoinduced electron transfer. This mechanism ensures high sensitivity and reliable quantification of NAD(P)H levels while minimizing interference from sensor concentration, excitation intensity, or environmental factors. Sensor was validated in HeLa and MD-MB453 cells under various metabolic and pharmacological conditions, including glucose and maltose stimulation and treatments with chemotherapeutic agents. Co-localization with mitochondrial-specific dyes confirmed its mitochondrial targeting, enabling precise tracking of NAD(P)H fluctuations. imaging of larvae under nutrient starvation or chemotherapeutic exposure revealed dose-dependent fluorescence responses, highlighting its potential for tracking NAD(P)H changes in live organisms. Sensor represents a significant advancement in NAD(P)H imaging, providing a powerful tool for exploring cellular metabolism and redox biology in biomedical research.
细胞内NAD(P)H浓度的检测和动态监测对于理解细胞代谢、氧化还原生物学及其在各种生理和病理过程中的作用至关重要。为满足这一需求,我们推出了传感器,一种用于实时、定量成像活细胞中NAD(P)H波动的近红外比率荧光传感器。传感器将一个缺电子的3-喹啉鎓受体与一种近红外罗丹明染料相结合,对NAD(P)H具有高灵敏度和特异性,并具有优异的光物理性质。在其未结合状态下,传感器在400nm激发时在650nm处发射强烈,在465nm处发射微弱。与NAD(P)H结合后,它在465nm处荧光增强,在650nm处荧光减弱,从而能够进行准确的比率测量。当在800或810nm激发时,传感器还表现出比率上转换荧光,为不同的实验设置提供了额外的灵活性。传感器的响应依赖于NAD(P)H对3-喹啉鎓受体的还原,形成一个1,4-二氢喹啉供体,该供体增强了465nm处的荧光,并通过光诱导电子转移淬灭了650nm处的近红外发射。这种机制确保了对NAD(P)H水平的高灵敏度和可靠定量,同时将传感器浓度、激发强度或环境因素的干扰降至最低。传感器在各种代谢和药理条件下,包括葡萄糖和麦芽糖刺激以及化疗药物处理的HeLa和MD-MB453细胞中得到了验证。与线粒体特异性染料的共定位证实了其线粒体靶向性,能够精确跟踪NAD(P)H的波动。对营养饥饿或化疗暴露下的幼虫进行成像显示出剂量依赖性荧光反应,突出了其在跟踪活生物体中NAD(P)H变化方面的潜力。传感器代表了NAD(P)H成像的一项重大进展,为生物医学研究中探索细胞代谢和氧化还原生物学提供了一个强大的工具。
