A lysosome-targeting viscosity-sensitive fluorescent probe based on a novel functionalised near-infrared xanthene-indolium dye and its application in living cells

The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. , locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy , for...

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Published in	Journal of materials chemistry. B, Materials for biology and medicine Vol. 8; no. 38; pp. 8838 - 8844
Main Authors	Liu, Chang, Zhao, Tong, He, Song, Zhao, Liancheng, Zeng, Xianshun
Format	Journal Article
Language	English
Published	England Royal Society of Chemistry 07.10.2020
Subjects	Biological activity Biomonitoring Cells (biology) Confocal microscopy Fluorescence fluorescent dyes Fluorescent Dyes - chemical synthesis Fluorescent Dyes - chemistry Fluorescent indicators Glycerol HeLa Cells Humans I.R. radiation indoles Indoles - chemical synthesis Indoles - chemistry Lysosomes Lysosomes - chemistry Lysosomes - metabolism Microscopy, Confocal - methods Microscopy, Fluorescence - methods Morphology near infrared radiation Organoselenium Compounds - chemical synthesis Organoselenium Compounds - chemistry Temporal resolution Viscosity Xanthene xanthenes Xanthenes - chemical synthesis Xanthenes - chemistry
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Abstract	The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. , locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy , for monitoring viscosity changes in biological systems. The Lyso-cy probe showed very strong fluorescence emission at around 710 nm in viscous media. The fluorescence intensity of Lyso-cy increased 122-fold from when in water to when in 95% glycerol. Moreover, Lyso-cy proved to be an ideal lysosome-targeting tracer for monitoring fluctuations in the viscosity of a living cell with high spatial and temporal resolution under laser confocal microscopy. The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. , locations, morphologies, and components.
AbstractList	The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. , locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy , for monitoring viscosity changes in biological systems. The Lyso-cy probe showed very strong fluorescence emission at around 710 nm in viscous media. The fluorescence intensity of Lyso-cy increased 122-fold from when in water to when in 95% glycerol. Moreover, Lyso-cy proved to be an ideal lysosome-targeting tracer for monitoring fluctuations in the viscosity of a living cell with high spatial and temporal resolution under laser confocal microscopy. The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g., locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy, for monitoring viscosity changes in biological systems. The Lyso-cy probe showed very strong fluorescence emission at around 710 nm in viscous media. The fluorescence intensity of Lyso-cy increased 122-fold from when in water to when in 95% glycerol. Moreover, Lyso-cy proved to be an ideal lysosome-targeting tracer for monitoring fluctuations in the viscosity of a living cell with high spatial and temporal resolution under laser confocal microscopy. The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g., locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy, for monitoring viscosity changes in biological systems. The Lyso-cy probe showed very strong fluorescence emission at around 710 nm in viscous media. The fluorescence intensity of Lyso-cy increased 122-fold from when in water to when in 95% glycerol. Moreover, Lyso-cy proved to be an ideal lysosome-targeting tracer for monitoring fluctuations in the viscosity of a living cell with high spatial and temporal resolution under laser confocal microscopy.The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g., locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy, for monitoring viscosity changes in biological systems. The Lyso-cy probe showed very strong fluorescence emission at around 710 nm in viscous media. The fluorescence intensity of Lyso-cy increased 122-fold from when in water to when in 95% glycerol. Moreover, Lyso-cy proved to be an ideal lysosome-targeting tracer for monitoring fluctuations in the viscosity of a living cell with high spatial and temporal resolution under laser confocal microscopy. The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. , locations, morphologies, and components. Herein, we constructed a novel near-infrared (NIR) lysosome-targeting viscosity probe, Lyso-cy , for monitoring viscosity changes in biological systems. The Lyso-cy probe showed very strong fluorescence emission at around 710 nm in viscous media. The fluorescence intensity of Lyso-cy increased 122-fold from when in water to when in 95% glycerol. Moreover, Lyso-cy proved to be an ideal lysosome-targeting tracer for monitoring fluctuations in the viscosity of a living cell with high spatial and temporal resolution under laser confocal microscopy. The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. , locations, morphologies, and components.
Author	Zhao, Tong Zeng, Xianshun Zhao, Liancheng Liu, Chang He, Song
AuthorAffiliation	Ministry of Education Harbin Institute of Technology School of Materials Science and Engineering School of Materials Science & Engineering Tianjin University of Technology Tianjin Key Laboratory for Photoelectric Materials and Devices Institute of Information Functional Materials& Devices Key Laboratory of Display Materials and Photoelectric Devices
AuthorAffiliation_xml	– name: School of Materials Science & Engineering – name: Tianjin Key Laboratory for Photoelectric Materials and Devices – name: Institute of Information Functional Materials& Devices – name: Tianjin University of Technology – name: School of Materials Science and Engineering – name: Ministry of Education – name: Harbin Institute of Technology – name: Key Laboratory of Display Materials and Photoelectric Devices
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Snippet	The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g. ,... The viscosity of lysosomes plays a significant role in modulating biological processes and reflects the status and function of this kind of organelle, e.g.,...
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SubjectTerms	Biological activity Biomonitoring Cells (biology) Confocal microscopy Fluorescence fluorescent dyes Fluorescent Dyes - chemical synthesis Fluorescent Dyes - chemistry Fluorescent indicators Glycerol HeLa Cells Humans I.R. radiation indoles Indoles - chemical synthesis Indoles - chemistry Lysosomes Lysosomes - chemistry Lysosomes - metabolism Microscopy, Confocal - methods Microscopy, Fluorescence - methods Morphology near infrared radiation Organoselenium Compounds - chemical synthesis Organoselenium Compounds - chemistry Temporal resolution Viscosity Xanthene xanthenes Xanthenes - chemical synthesis Xanthenes - chemistry
Title	A lysosome-targeting viscosity-sensitive fluorescent probe based on a novel functionalised near-infrared xanthene-indolium dye and its application in living cells
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