Fluorescence Techniques to Study Lipid Dynamics

Sezgin, Erdinç; Schwille, Petra

doi:10.1101/cshperspect.a009803

Cited by 91 publications

(70 citation statements)

References 238 publications

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“…The concept of sphingolipid-sterol-protein rafts that were smaller than the resolution of the optical microscope stimulated the search for novel methodologies. Recent studies using different imaging and spectroscopic methods have revealed interesting glimpses of how the lipids and proteins behave in the crowded bilayer (Sezgin and Schwille 2011). These studies have confirmed the existence of cholesteroldependent nanoscale assemblies of sphingolipids and GPI-anchored proteins in the plasma membrane of living cells.…”

Section: The Dynamic Organization Of the Plasma Membranementioning

confidence: 58%

Membrane Organization and Lipid Rafts

Simons¹,

Sampaio²

2011

Cold Spring Harbor Perspectives in Biology

884

771

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Cell membranes are composed of a lipid bilayer, containing proteins that span the bilayer and/or interact with the lipids on either side of the two leaflets. Although recent advances in lipid analytics show that membranes in eukaryotic cells contain hundreds of different lipid species, the function of this lipid diversity remains enigmatic. The basic structure of cell membranes is the lipid bilayer, composed of two apposing leaflets, forming a twodimensional liquid with fascinating properties designed to perform the functions cells require. To coordinate these functions, the bilayer has evolved the propensity to segregate its constituents laterally. This capability is based on dynamic liquid-liquid immiscibility and underlies the raft concept of membrane subcompartmentalization. This principle combines the potential for sphingolipid-cholesterol self-assembly with protein specificity to focus and regulate membrane bioactivity. Here we will review the emerging principles of membrane architecture with special emphasis on lipid organization and domain formation.

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Section: The Dynamic Organization Of the Plasma Membranementioning

confidence: 58%

Membrane Organization and Lipid Rafts

Simons¹,

Sampaio²

2011

Cold Spring Harbor Perspectives in Biology

884

771

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“…Although confocal microscopy studies have reported co-localization of certain molecules with putative lipid raft markers (such as cholera toxin) as evidence of their raft association 44 , in general the resolution of such systems is insufficient to directly assay raft domain structure and composition. To overcome this limitation, several optical tools have recently been developed 45,46 and applied to investigate nano-scale structures and dynamics in cells. For instance, super-resolution optical microscopy approaches such as photoactivated localization microscopy (PALM), stimulated emission depletion (STED) microscopy (Supplementary Box S2), and near-field scanning optical microscopy (NSOM) have been used to visualize lipid-mediated protein clustering 47–50 .…”

Section: Studying Lipid Raftsmentioning

confidence: 99%

The mystery of membrane organization: composition, regulation and roles of lipid rafts

Sezgin

Levental

Mayor

et al. 2017

Nat Rev Mol Cell Biol

1,546

1,599

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Cellular plasma membranes are laterally heterogeneous, featuring a variety of distinct subcompartments that differ in their biophysical properties and composition. A large body of research has focused on understanding the basis for this heterogeneity and its physiological relevance. The membrane raft hypothesis formalized a physicochemical principle for a subtype of such lateral membrane heterogeneity, wherein the preferential associations of cholesterol and saturated lipids drives the formation of relatively packed (ordered) membrane domains that selectively recruit certain lipids and proteins. Recent years have yielded new insights into this concept and its in vivo relevance, primarily owing to the development of biochemical and biophysical technologies.

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“…Figure 2B compares values of the partitioning coeffi cient %Lo for the different Chol analogs. Due to the compositional complexity, the molecular Here, d ( P STED ) and D ( P STED ) are the diameter of the observation spot and the average transit time at the STED power, P STED , and d ( P STED = 0) and D ( P STED = 0) the respective parameters at confocal recordings, where the diameter of the confocal spot [ d ( P STED = 0) = 200 nm for 488 nm and 240 nm for 635 nm excitation] has been determined from imaging fl uorescent beads or from theory ( 36 ). Shortening of the transit time D due to photobleaching from the STED laser is unlikely, as has been shown by several control measurements before, i.e., the decrease in d with STED power P STED is not a result of photobleaching by the STED laser [e.g., ( 37,38 )].…”

Section: Colocalization Analysismentioning

confidence: 99%