Filters

2018 - 201952020 - 20213

More filters

2020 - 20238
Reset filters

Settings

Author: Eggeling, Christian × Author: Sezgin, Erdinc × End date: 2024 × DDC: 570 × Has files: Yes ×

Search Results

Now showing 1 - 8 of 8
  • Thumbnail Image
    Item
    Nanoscale dynamics of cholesterol in the cell membrane
    (Bethesda, Md. : ASBMB Publications, 2019) Pinkwart, Kerstin; Schneider, Falk; Lukoseviciute, Martyna; Sauka-Spengler, Tatjana; Lyman, Edward; Eggeling, Christian; Sezgin, Erdinc
    Cholesterol constitutes ~30-40% of the mammalian plasma membrane, a larger fraction than of any other single component. It is a major player in numerous signaling processes as well as in shaping molecular membrane architecture. However, our knowledge of the dynamics of cholesterol in the plasma membrane is limited, restricting our understanding of the mechanisms regulating its involvement in cell signaling. Here, we applied advanced fluorescence imaging and spectroscopy approaches on in vitro (model membranes) and in vivo (live cells and embryos) membranes as well as in silico analysis to systematically study the nanoscale dynamics of cholesterol in biological membranes. Our results indicate that cholesterol diffuses faster than phospholipids in live membranes, but not in model membranes. Interestingly, a detailed statistical diffusion analysis suggested two-component diffusion for cholesterol in the plasma membrane of live cells. One of these components was similar to a freely diffusing phospholipid analogue, whereas the other one was significantly faster. When a cholesterol analogue was localized to the outer leaflet only, the fast diffusion of cholesterol disappeared, and it diffused similarly to phospholipids. Overall, our results suggest that cholesterol diffusion in the cell membrane is heterogeneous and that this diffusional heterogeneity is due to cholesterol's nanoscale interactions and localization in the membrane. © 2019 Pinkwart et al. Published by The American Society for Biochemistry and Molecular Biology, Inc.
  • Thumbnail Image
    Item
    How to minimize dye-induced perturbations while studying biomembrane structure and dynamics: PEG linkers as a rational alternative
    (Amsterdam : Elsevier, 2018) Mobarak, Edouard; Javanainen, Matti; Kulig, Waldemar; Honigmann, Alf; Sezgin, Erdinc; Aho, Noora; Eggeling, Christian; Rog, Tomasz; Vattulainen, Ilpo
    Organic dye-tagged lipid analogs are essential for many fluorescence-based investigations of complex membrane structures, especially when using advanced microscopy approaches. However, lipid analogs may interfere with membrane structure and dynamics, and it is not obvious that the properties of lipid analogs would match those of non-labeled host lipids. In this work, we bridged atomistic simulations with super-resolution imaging experiments and biomimetic membranes to assess the performance of commonly used sphingomyelin-based lipid analogs. The objective was to compare, on equal footing, the relative strengths and weaknesses of acyl chain labeling, headgroup labeling, and labeling based on poly-ethyl-glycol (PEG) linkers in determining biomembrane properties. We observed that the most appropriate strategy to minimize dye-induced membrane perturbations and to allow consideration of Brownian-like diffusion in liquid-ordered membrane environments is to decouple the dye from a membrane by a PEG linker attached to a lipid headgroup. Yet, while the use of PEG linkers may sound a rational and even an obvious approach to explore membrane dynamics, the results also suggest that the dyes exploiting PEG linkers interfere with molecular interactions and their dynamics. Overall, the results highlight the great care needed when using fluorescent lipid analogs, in particular accurate controls.
  • Thumbnail Image
    Item
    Mechanical properties of plasma membrane vesicles correlate with lipid order, viscosity and cell density
    (Berlin : Nature Publishing, 2019) Steinkühler, Jan; Sezgin, Erdinc; Urbančič, Iztok; Eggeling, Christian; Dimova, Rumiana
    Regulation of plasma membrane curvature and composition governs essential cellular processes. The material property of bending rigidity describes the energetic cost of membrane deformations and depends on the plasma membrane molecular composition. Because of compositional fluctuations and active processes, it is challenging to measure it in intact cells. Here, we study the plasma membrane using giant plasma membrane vesicles (GPMVs), which largely preserve the plasma membrane lipidome and proteome. We show that the bending rigidity of plasma membranes under varied conditions is correlated to readout from environment-sensitive dyes, which are indicative of membrane order and microviscosity. This correlation holds across different cell lines, upon cholesterol depletion or enrichment of the plasma membrane, and variations in cell density. Thus, polarity- and viscosity-sensitive probes represent a promising indicator of membrane mechanical properties. Additionally, our results allow for identifying synthetic membranes with a few well defined lipids as optimal plasma membrane mimetics.
  • Thumbnail Image
    Item
    Reconstitution of immune cell interactions in free-standing membranes
    (Cambridge : Company of Biologists, 2019) Jenkins, Edward; Santos, Ana M.; Felce, James H; Hatherley, Deborah; Dustin, Michael L.; Davis, Simon J.; Eggeling, Christian; Sezgin, Erdinc
    The spatiotemporal regulation of signalling proteins at the contacts formed between immune cells and their targets determines how and when immune responses begin and end. Therapeutic control of immune responses therefore relies on thorough elucidation of the molecular processes occurring at these interfaces. However, the detailed investigation of each component's contribution to the formation and regulation of the contact is hampered by the complexities of cell composition and architecture. Moreover, the transient nature of these interactions creates additional challenges, especially in the use of advanced imaging technology. One approach that circumvents these problems is to establish in vitro systems that faithfully mimic immune cell interactions, but allow complexity to be ‘dialled-in’ as needed. Here, we present an in vitro system that makes use of synthetic vesicles that mimic important aspects of immune cell surfaces. Using this system, we began to explore the spatial distribution of signalling molecules (receptors, kinases and phosphatases) and how this changes during the initiation of signalling. The GUV/cell system presented here is expected to be widely applicable.The spatiotemporal regulation of signalling proteins at the contacts formed between immune cells and their targets determines how and when immune responses begin and end. Therapeutic control of immune responses therefore relies on thorough elucidation of the molecular processes occurring at these interfaces. However, the detailed investigation of each component's contribution to the formation and regulation of the contact is hampered by the complexities of cell composition and architecture. Moreover, the transient nature of these interactions creates additional challenges, especially in the use of advanced imaging technology. One approach that circumvents these problems is to establish in vitro systems that faithfully mimic immune cell interactions, but allow complexity to be ‘dialled-in’ as needed. Here, we present an in vitro system that makes use of synthetic vesicles that mimic important aspects of immune cell surfaces. Using this system, we began to explore the spatial distribution of signalling molecules (receptors, kinases and phosphatases) and how this changes during the initiation of signalling. The GUV/cell system presented here is expected to be widely applicable.
  • Thumbnail Image
    Item
    Creating supported plasma membrane bilayers using acoustic pressure
    (Basel : MDPI, 2020) Sezgin, Erdinc; Carugo, Dario; Levental, Ilya; Stride, Eleanor; Eggeling, Christian
    Model membrane systems are essential tools for the study of biological processes in a simplified setting to reveal the underlying physicochemical principles. As cell-derived membrane systems, giant plasma membrane vesicles (GPMVs) constitute an intermediate model between live cells and fully artificial structures. Certain applications, however, require planar membrane surfaces. Here, we report a new approach for creating supported plasma membrane bilayers (SPMBs) by bursting cell-derived GPMVs using ultrasound within a microfluidic device. We show that the mobility of outer leaflet molecules is preserved in SPMBs, suggesting that they are accessible on the surface of the bilayers. Such model membrane systems are potentially useful in many applications requiring detailed characterization of plasma membrane dynamics. © 2020 by the authors. Licensee MDPI, Basel, Switzerland.
  • Thumbnail Image
    Item
    More Favorable Palmitic Acid Over Palmitoleic Acid Modification of Wnt3 Ensures Its Localization and Activity in Plasma Membrane Domains
    (Lausanne : Frontiers Media, 2019) Azbazdar, Yagmur; Ozalp, Ozgun; Sezgin, Erdinc; Veerapathiran, Sapthaswaran; Duncan, Anna L.; Sansom, Mark S.P.; Eggeling, Christian; Wohland, Thorsten; Karaca, Ezgi; Ozhan, Gunes
    While the lateral organization of plasma membrane components has been shown to control binding of Wnt ligands to their receptors preferentially in the ordered membrane domains, the role of posttranslational lipid modification of Wnt on this selective binding is unknown. Here, we identify that the canonical Wnt is presumably acylated by palmitic acid, a saturated 16-carbon fatty acid, at a conserved serine residue. Acylation of Wnt3 is dispensable for its secretion and binding to Fz8 while it is essential for Wnt3's proper binding and domain-like diffusion in the ordered membrane domains. We further unravel that non-palmitoylated Wnt3 is unable to activate Wnt/β-catenin signaling either in zebrafish embryos or in mammalian cells. Based on these results, we propose that the lipidation of canonical Wnt, presumably by a saturated fatty acid, determines its competence in interacting with the receptors in the appropriate domains of the plasma membrane, ultimately keeping the signaling activity under control. © Copyright © 2019 Azbazdar, Ozalp, Sezgin, Veerapathiran, Duncan, Sansom, Eggeling, Wohland, Karaca and Ozhan.
  • Thumbnail Image
    Item
    z-STED Imaging and Spectroscopy to Investigate Nanoscale Membrane Structure and Dynamics
    (Bethesda, Md. : Biophysical Soc., 2020) Barbotin, Aurélien; Urbančič, Iztok; Galiani, Silvia; Eggeling, Christian; Booth, Martin; Sezgin, Erdinc
    Super-resolution stimulated emission depletion (STED) microcopy provides optical resolution beyond the diffraction limit. The resolution can be increased laterally (xy) or axially (z). Two-dimensional STED has been extensively used to elucidate the nanoscale membrane structure and dynamics via imaging or combined with spectroscopy techniques such as fluorescence correlation spectroscopy (FCS) and spectral imaging. On the contrary, z-STED has not been used in this context. Here, we show that a combination of z-STED with FCS or spectral imaging enables us to see previously unobservable aspects of cellular membranes. We show that thanks to an axial resolution of ∼100 nm, z-STED can be used to distinguish axially close-by membranes, early endocytic vesicles, or tubular membrane structures. Combination of z-STED with FCS and spectral imaging showed diffusion dynamics and lipid organization in these structures, respectively. © 2020 Biophysical Society
  • Thumbnail Image
    Item
    Aggregation and mobility of membrane proteins interplay with local lipid order in the plasma membrane of T cells
    (Chichester : Wiley, 2021) Urbančič, Iztok; Schiffelers, Lisa; Jenkins, Edward; Gong, Weijian; Santos, Ana Mafalda; Schneider, Falk; O'Brien-Ball, Caitlin; Vuong, Mai Tuyet; Ashman, Nicole; Sezgin, Erdinc; Eggeling, Christian
    To disentangle the elusive lipid-protein interactions in T-cell activation, we investigate how externally imposed variations in mobility of key membrane proteins (T-cell receptor [TCR], kinase Lck, and phosphatase CD45) affect the local lipid order and protein colocalisation. Using spectral imaging with polarity-sensitive membrane probes in model membranes and live Jurkat T cells, we find that partial immobilisation of proteins (including TCR) by aggregation or ligand binding changes their preference towards a more ordered lipid environment, which can recruit Lck. Our data suggest that the cellular membrane is poised to modulate the frequency of protein encounters upon alterations of their mobility, for example in ligand binding, which offers new mechanistic insight into the involvement of lipid-mediated interactions in membrane-hosted signalling events.