Fluorescent probes for detecting cholesterol-rich ordered membrane microdomains: entangled relationships between structural analogies in the membrane and functional homologies in the cell

Gérald Gaibelet; François Tercé; Sophie Allart; Chantal Lebrun; Xavier Collet; Nadège Jamin; Stéphane Orlowski; Gérald Gaibelet; François Tercé; Sophie Allart; Chantal Lebrun; Xavier Collet; Nadège Jamin; Stéphane Orlowski

doi:10.3934/biophy.2017.1.121

AIMS Biophysics

2017, Volume 4, Issue 1: 121-151. doi: 10.3934/biophy.2017.1.121

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Review Special Issues

Fluorescent probes for detecting cholesterol-rich ordered membrane microdomains: entangled relationships between structural analogies in the membrane and functional homologies in the cell

1.
Theranyx SA, Marseille, France
2.
Université Toulouse III, UMR 1048 INSERM, Toulouse, France
3.
Plateau Technique d’Imagerie Cellulaire, INSERM U1043, Toulouse, France
4.
Université Toulouse III, Toxalim UMR 1331 INRA, ENVT, Toulouse, France
5.
IBiTecS/SB2SM CEA and I2BC UMR 9198 CNRS, Université Paris-Saclay, Gif-sur-Yvette, France

Received: 20 December 2016 Accepted: 15 February 2017 Published: 21 February 2017

This review addresses the question of fluorescent detection of ordered membrane (micro) domains in living (cultured) cells, with a “practical” point of view since the situation is much more complicated than for studying model membranes. We first briefly recall the bases of model membrane structural organization involving liquid-ordered and -disordered phases, and the main features of their counterparts in cell membranes that are the various microdomains. We then emphasize the utility of the fluorescent probes derived from cholesterol, and delineate the respective advantages, limitations and drawbacks of the existing ones. In particular, besides their intra-membrane behavior, their relevant characteristics should integrate their different cellular fates for membrane turn-over, trafficking and metabolism, in order to evaluate and improve their efficiency for in-situ probing membrane microdomains in the cell physiology context. Finally, at the present stage, it appears that Bdp-Chol and Pyr-met-Chol display well complementary properties, allowing to use them in combination to improve the reliability of the current experimental approaches. But the field is still open, and there remains much work to perform in this research area.
- membrane domains,
- ordered membranes,
- lipid rafts,
- cholesterol,
- fluorescence,
- intracellular trafficking
Citation: Gérald Gaibelet, François Tercé, Sophie Allart, Chantal Lebrun, Xavier Collet, Nadège Jamin, Stéphane Orlowski. Fluorescent probes for detecting cholesterol-rich ordered membrane microdomains: entangled relationships between structural analogies in the membrane and functional homologies in the cell[J]. AIMS Biophysics, 2017, 4(1): 121-151. doi: 10.3934/biophy.2017.1.121

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Abstract

This review addresses the question of fluorescent detection of ordered membrane (micro) domains in living (cultured) cells, with a “practical” point of view since the situation is much more complicated than for studying model membranes. We first briefly recall the bases of model membrane structural organization involving liquid-ordered and -disordered phases, and the main features of their counterparts in cell membranes that are the various microdomains. We then emphasize the utility of the fluorescent probes derived from cholesterol, and delineate the respective advantages, limitations and drawbacks of the existing ones. In particular, besides their intra-membrane behavior, their relevant characteristics should integrate their different cellular fates for membrane turn-over, trafficking and metabolism, in order to evaluate and improve their efficiency for in-situ probing membrane microdomains in the cell physiology context. Finally, at the present stage, it appears that Bdp-Chol and Pyr-met-Chol display well complementary properties, allowing to use them in combination to improve the reliability of the current experimental approaches. But the field is still open, and there remains much work to perform in this research area.

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