Facile construction of dual-response super-resolution probes for tracking organelles dynamics

Daili Liu, Guiqian Fang, Yanfeng Wang, Caicai Meng, Zhidong Liu, Qixin Chen, Xintian Shao
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Abstract

Super-resolution imaging techniques, such as structured illumination microscopy (SIM), have enabled researchers to obtain nanoscale organelle-level outputs in living systems, but they impose additional stringent requirements on fluorescence probes. However, high-performance, custom-designed SIM probes that can explain underlying biological processes remain unavailable. Herein, a customizable engineering toolkit is developed for the facile assembly of SIM probes suitable for subcellular component detection. This toolkit is used to customize a fluorescent molecule, CPC (coumarin–phenylhydrazine–carboxyl), capable of simultaneously monitoring peroxynitrite (ONOO) and polarity distribution in mitochondria and lipid droplets (LDs), respectively, through functional ON–OFF mechanisms. The customized CPC molecule demonstrated excellent imaging capabilities under SIM, enabled the successful localization of multiple organelles, and reliably tracked the distribution of different components, thus facilitating the study of the interplay between organelles. Using CPC, the physical transition of intracellular LDs is demonstrated from heterogeneity to homogeneity. This was specifically observed during ferroptosis where the polarity of the LDs increased and their morphology became more contracted. Furthermore, the loss of LDs functionality could not counteract the accumulation of ONOO within the mitochondria, leading to the decoupling of mitochondrial LDs during ferroptosis. These results confirmed the potential mechanism of LDs dysfunction and decoupling triggered via cumulative mitochondrial oxidative stress during ferroptosis. To summarize, this toolkit will be a powerful tool for examining subtle variations among components during the interplay between different organelles, thus offering novel avenues for understanding and treating related diseases.

Abstract Image

轻松构建用于跟踪细胞器动态的双响应超分辨率探针
结构照明显微镜(SIM)等超分辨率成像技术使研究人员能够获得生命系统中纳米级细胞器水平的输出,但它们对荧光探针提出了额外的严格要求。然而,能够解释潜在生物过程的高性能、定制设计的 SIM 探针仍未问世。本文开发了一种可定制的工程工具包,用于简便地组装适用于亚细胞成分检测的 SIM 探针。该工具包被用于定制一种荧光分子 CPC(香豆素-苯肼-羧基),它能够通过功能性开-关机制同时监测线粒体和脂滴中的过氧化亚硝酸盐(ONOO-)和极性分布。定制的 CPC 分子在 SIM 下表现出卓越的成像能力,能够成功定位多个细胞器,并可靠地跟踪不同成分的分布,从而促进了细胞器之间相互作用的研究。利用 CPC,细胞内 LD 的物理变化从异质性转变为均质性。在铁突变过程中,LDs 的极性增强,形态变得更加收缩,这一点被特别观察到。此外,线粒体 LDs 功能的丧失无法抵消线粒体内 ONOO- 的积累,从而导致线粒体 LDs 在铁突变过程中脱钩。这些结果证实了线粒体 LDs 功能失调和脱钩的潜在机制,即在铁蜕变过程中通过累积线粒体氧化应激引发线粒体 LDs 功能失调和脱钩。总之,该工具包将成为研究不同细胞器相互作用过程中各组分之间微妙变化的有力工具,从而为了解和治疗相关疾病提供新的途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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