Mobility in geometrically confined membranes

Domanov, Yegor A.; Aimon, Sophie; Toombes, Gilman E. S.; Renner, Marianne; Quemeneur, François; Triller, Antoine; Turner, Matthew S.; Bassereau, Patricia

doi:10.1073/pnas.1102646108

Cited by 98 publications

(106 citation statements)

References 43 publications

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“…The mobility of DiI decreased as the molecules approached the tips of filopodia or spines (Fig. 3E), possibly due to the higher local membrane curvature (36) and the different composition of membrane proteins at these locations.…”

Section: Resultsmentioning

confidence: 99%

Super-resolution fluorescence imaging of organelles in live cells with photoswitchable membrane probes

Shim

Xia

Zhong

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

445

449

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Imaging membranes in live cells with nanometer-scale resolution promises to reveal ultrastructural dynamics of organelles that are essential for cellular functions. In this work, we identified photoswitchable membrane probes and obtained super-resolution fluorescence images of cellular membranes. We demonstrated the photoswitching capabilities of eight commonly used membrane probes, each specific to the plasma membrane, mitochondria, the endoplasmic recticulum (ER) or lysosomes. These small-molecule probes readily label live cells with high probe densities. Using these probes, we achieved dynamic imaging of specific membrane structures in living cells with 30-60 nm spatial resolution at temporal resolutions down to 1-2 s. Moreover, by using spectrally distinguishable probes, we obtained two-color super-resolution images of mitochondria and the ER. We observed previously obscured details of morphological dynamics of mitochondrial fusion/fission and ER remodeling, as well as heterogeneous membrane diffusivity on neuronal processes.nanoscopy | diffraction limit | photoswitchable dye | stochastic optical reconstruction microscopy | photoactivation localization microscopy

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Section: Resultsmentioning

confidence: 99%

Super-resolution fluorescence imaging of organelles in live cells with photoswitchable membrane probes

Shim

Xia

Zhong

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

445

449

View full text Add to dashboard Cite

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“…27). It is thus likely that curvature will amplify this effect, as curvature significantly reduces protein diffusion 28 and also affects lipids dynamics 26 . Under such conditions, one would expect that the transient segregation of PtdIns(4,5)P 2 generates a positive feedback, allowing proteins that selectively interact with PtdIns(4,5)P 2 to locally accumulate on PtdIns(4,5)P 2 -enriched areas, independently of their ability to polymerize (that is, AP180 and Epsin2).…”

Section: Articlementioning

confidence: 99%

BIN1/M-Amphiphysin2 induces clustering of phosphoinositides to recruit its downstream partner dynamin

Picas¹,

Viaud²,

Schauer³

et al. 2014

Nat Commun

Self Cite

103

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Phosphoinositides play a central role in many physiological processes by assisting the recruitment of proteins to membranes through specific phosphoinositide-binding motifs. How this recruitment is coordinated in space and time is not well understood. Here we show that BIN1/M-Amphiphysin2, a protein involved in T-tubule biogenesis in muscle cells and frequently mutated in centronuclear myopathies, clusters PtdIns(4,5)P 2 to recruit its downstream partner dynamin. By using several mutants associated with centronuclear myopathies, we find that the N-BAR and the SH3 domains of BIN1 control the kinetics and the accumulation of dynamin on membranes, respectively. We show that phosphoinositide clustering is a mechanism shared by other proteins that interact with PtdIns(4,5)P 2 , but do not contain a BAR domain. Our numerical simulations point out that clustering is a diffusion-driven process in which phosphoinositide molecules are not sequestered. We propose that this mechanism plays a key role in the recruitment of downstream phosphoinositide-binding proteins.

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“…Experimental measurements of L sd for lipid bilayer systems are typically in the 100 nm to micron range. 24,25,[38][39][40][41][42] In coarse-grained models, some details of lipid and solvent structure are lost and there is no reason to expect close correspondence to experimental numbers. For example, in the coarse-grained MARTINI force field, 5 η m has been determined to be 1.2 × 10 −8 P cm for DPPC bilayers, with water viscosity η f = 7 × 10 −3 P. 9 Within MARTINI simulations, we expect L sd ≈ 8.6 nm-much smaller than the experimental range.…”

Section: Prediction Of Diffusion Coefficients In the Periodic Boxmentioning

confidence: 99%

Strong influence of periodic boundary conditions on lateral diffusion in lipid bilayer membranes

Camley

Lerner

Pastor

et al. 2015

The Journal of Chemical Physics

124

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The Saffman-Delbrück hydrodynamic model for lipid-bilayer membranes is modified to account for the periodic boundary conditions commonly imposed in molecular simulations. Predicted lateral diffusion coefficients for membrane-embedded solid bodies are sensitive to box shape and converge slowly to the limit of infinite box size, raising serious doubts for the prospects of using detailed simulations to accurately predict membrane-protein diffusivities and related transport properties. Estimates for the relative error associated with periodic boundary artifacts are 50% and higher for fully atomistic models in currently feasible simulation boxes. MARTINI simulations of LacY membrane protein diffusion and LacY dimer diffusion in DPPC membranes and lipid diffusion in pure DPPC bilayers support the underlying hydrodynamic model. C 2015 AIP Publishing LLC. [http://dx

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Mobility in geometrically confined membranes

Cited by 98 publications

References 43 publications

Super-resolution fluorescence imaging of organelles in live cells with photoswitchable membrane probes

Super-resolution fluorescence imaging of organelles in live cells with photoswitchable membrane probes

BIN1/M-Amphiphysin2 induces clustering of phosphoinositides to recruit its downstream partner dynamin

Strong influence of periodic boundary conditions on lateral diffusion in lipid bilayer membranes

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