硫黄素
化学
化学发光
蛋白质聚集
蛋白质折叠
体内
淀粉样蛋白(真菌学)
费斯特共振能量转移
临床前影像学
淀粉样β
细胞生物学
生物物理学
神经退行性变
光学成像
分子成像
共核细胞病
神经科学
蛋白酶体
生物化学
泛素
蛋白质稳态
淀粉样疾病
作者
Biyue Zhu,Zhenhua Liu,Richard Van,Huizhe Wang,Shi Kuang,Yuntao Jia,Erick Calderon Leon,Fan Yang,Jing Zhang,Jun Yang,Howard Hong,Fleur Lobo,Astra Yu,Johnson Wang,Tanzi Re,C. Zhang,Xiaobo Mao,Yihan Shao,Chongzhao Ran
标识
DOI:10.1073/pnas.2513311123
摘要
Protein misfolding in the brain is a key pathological hallmark of neurodegenerative diseases. Optical imaging of misfolded proteins in disease models is essential for elucidating etiology and early diagnosis. However, developing specific optical imaging probes for each misfolded protein is time-consuming and challenging, leaving many pathological targets without effective detection tools, especially for in vivo imaging. Here, we present a dual-mode chemiluminescence strategy that enables both generic and specific detection of misfolded proteins using a single probe platform. In the generic mode, we demonstrate that ADLumin-1, a chemiluminescent probe, enables highly sensitive detection of diverse misfolded proteins in vitro, achieving up to 128-fold higher signal enhancement than Thioflavin T, and allows noninvasive imaging in mice models of Parkinson's disease, Alzheimer's disease, and amyotrophic lateral sclerosis. In the specific mode, ADLumin-1 combined with protein misfolding cyclic amplification allows femtomolar-level detection of α-synuclein in cerebrospinal fluid, while integration with a bio-orthogonal chemiluminescence resonance energy transfer technique enables in vivo discrimination of α-synuclein from Aβ. This dual-mode, modular approach offers a practical solution to the current probe limitations, with potential preclinical and clinical applications in neurodegenerative disorders.
科研通智能强力驱动
Strongly Powered by AbleSci AI