An ER-targeted “reserve-release” fluorogen for topological quantification of reticulophagy

The endoplasmic reticulum's (ER) dynamic nature, essential for maintaining cellular homeostasis, can be influenced by stress-induced damage, which can be assessed by examining the morphology of ER dynamics and, more locally, ER properties such as hydrophobicity, viscosity, and polarity. Althoug...

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Bibliographic Details
Published in:Biomaterials 2023-01, Vol.292, p.121929-121929, Article 121929
Main Authors: Fang, Hongbao, Hu, Lianting, Chen, Qixin, Geng, Shanshan, Qiu, Kangqiang, Wang, Chengjun, Hao, Mingang, Tian, Zhiqi, Chen, Huimin, Liu, Lei, Guan, Jun-Lin, Chen, Yuncong, Dong, Lei, Guo, Zijian, He, Weijiang, Diao, Jiajie
Format: Article
Language:English
Subjects:
Autophagy
Endoplasmic Reticulum
Endoplasmic Reticulum Stress
ER dynamics
Molecular probe
Reticulophagy
Super-resolution imaging
Topological analysis
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Summary:The endoplasmic reticulum's (ER) dynamic nature, essential for maintaining cellular homeostasis, can be influenced by stress-induced damage, which can be assessed by examining the morphology of ER dynamics and, more locally, ER properties such as hydrophobicity, viscosity, and polarity. Although numerous ER-specific chemical probes have been developed to monitor the ER's physical and chemical parameters, the quantitative detection and super-resolution imaging of its local hydrophobicity have yet to be explored. Here, we describe a photostable ER-targeted probe with high signal-to-noise ratio for super-resolution imaging that can specifically respond to changes in ER hydrophobicity under stress based on a “reserve-release” mechanism. The probe shows an excellent ability to target ER over commercial ER dyes and can be used to track local changes of hydrophobicity by fluorescence intensity and morphology during the selective autophagy of ER (i.e., reticulophagy). By correlating the level and location of ER damage with the distribution of fluorescence intensity, we were able to assess reticulophagy at the subcellular level. Beyond that, we developed a topological analytical tool adaptable to any ER probe for detecting structural changes in ER and thus quantitatively identifying reticulophagy. The algorithm-assisted tool can also be adapted to a wide range of molecular probes and organelles. Altogether, the new probe and analytical strategy described here show promise for the quantitative detection and analysis of subtle ER damage and stress. [Display omitted] •We developed a “reserve-release” mechanism for ER-BDP, a photostable and low-toxicity probe for super-resolution imaging.•This ER-targeting lipophilic fluorescent probe is able to sense local hydrophobicity change caused by reticulophagy.•We provide new insights into the design of super-resolution imaging probes for quantifying the subcellular microenvironment.•A new topological parameter has been introduced for a wide range of molecular probes and organelles.
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2022.121929