Feedback between membrane tension, lipid shape and curvature in the formation of packing defects

AbstractLipid packing defects favor the binding of proteins to cellular membranes by creating spaces between lipid head groups that allow the insertion of amphipathic helices or lipid modifications. The density of packing defects in a lipid membrane is well known to increase with membrane curvature and in the presence of conical-shaped lipids. In contrast, the role of membrane tension in the formation of lipid packing defects has been poorly investigated. Here we use a combination of numerical simulations and experiments to measure the effect of membrane tension on the density of lipid packing defects. We first monitor the binding of ALPS (amphipathic lipid packing sensor) to giant unilamellar vesicles and observe a striking periodic binding of ALPS that we attribute to osmotically-induced membrane tension and transient membrane pore formation. Using micropipette aspiration experiments, we show that a high membrane tension induces a reversible increase in the density of lipid packing defects. We next focus on packing defects induced by lipid shape and show that conical lipids generate packing defects similar to that induced by membrane tension and enhance membrane deformation due to the insertion of the ALPS helix. Both cyclic ALPS binding and the cooperative effect of ALPS binding and conical lipids on membrane deformation result from an interplay between helix insertion and lipid packing defects created by membrane tension, conical lipids and/or membrane curvature. We propose that feedback mechanisms involving membrane tension, lipid shape and membrane curvature play a crucial role in membrane deformation and intracellular transport events.

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Membrane re-modelling by BAR domain superfamily proteins via molecular and non-molecular factors

Biochemical Society Transactions ◽

10.1042/bst20170322 ◽

2018 ◽

Vol 46 (2) ◽

pp. 379-389 ◽

Cited By ~ 23

Author(s):

Tamako Nishimura ◽

Nobuhiro Morone ◽

Shiro Suetsugu

Keyword(s):

Lipid Membranes ◽

Intracellular Transport ◽

Lipid Membrane ◽

Membrane Curvature ◽

Membrane Dynamics ◽

Cytoskeletal Proteins ◽

Cellular Functions ◽

High Concentration ◽

Bar Domain ◽

Intracellular Organelles

Lipid membranes are structural components of cell surfaces and intracellular organelles. Alterations in lipid membrane shape are accompanied by numerous cellular functions, including endocytosis, intracellular transport, and cell migration. Proteins containing Bin–Amphiphysin–Rvs (BAR) domains (BAR proteins) are unique, because their structures correspond to the membrane curvature, that is, the shape of the lipid membrane. BAR proteins present at high concentration determine the shape of the membrane, because BAR domain oligomers function as scaffolds that mould the membrane. BAR proteins co-operate with various molecular and non-molecular factors. The molecular factors include cytoskeletal proteins such as the regulators of actin filaments and the membrane scission protein dynamin. Lipid composition, including saturated or unsaturated fatty acid tails of phospholipids, also affects the ability of BAR proteins to mould the membrane. Non-molecular factors include the external physical forces applied to the membrane, such as tension and friction. In this mini-review, we will discuss how the BAR proteins orchestrate membrane dynamics together with various molecular and non-molecular factors.

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A filter at the entrance of the Golgi that selects vesicles according to size and bulk lipid composition

eLife ◽

10.7554/elife.16988 ◽

2016 ◽

Vol 5 ◽

Cited By ~ 37

Author(s):

Maud Magdeleine ◽

Romain Gautier ◽

Pierre Gounon ◽

Hélène Barelli ◽

Stefano Vanni ◽

...

Keyword(s):

Lipid Composition ◽

Small Radius ◽

Phosphatidylcholine Liposomes ◽

Hydrophobic Residues ◽

Lipid Packing ◽

Transport Vesicles ◽

Packing Defects ◽

The Alps ◽

Curved Membranes

When small phosphatidylcholine liposomes are added to perforated cells, they bind preferentially to the Golgi suggesting an exceptional avidity of this organelle for curved membranes without stereospecific interactions. We show that the cis golgin GMAP-210 accounts for this property. First, the liposome tethering properties of the Golgi resembles that of the amphipathic lipid-packing sensor (ALPS) motif of GMAP-210: both preferred small (radius < 40 nm) liposomes made of monounsaturated but not saturated lipids. Second, reducing GMAP-210 levels or redirecting its ALPS motif to mitochondria decreased liposome capture by the Golgi. Extensive mutagenesis analysis suggests that GMAP-210 tethers authentic transport vesicles via the same mechanism whereby the ALPS motif senses lipid-packing defects at the vesicle surface through its regularly spaced hydrophobic residues. We conclude that the Golgi uses GMAP-210 as a filter to select transport vesicles according to their size and bulk lipid composition.

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The roles of the diversity of amphipathic lipids in shaping membranes by membrane-shaping proteins

Biochemical Society Transactions ◽

10.1042/bst20190376 ◽

2020 ◽

Vol 48 (3) ◽

pp. 837-851

Author(s):

Manabu Kitamata ◽

Takehiko Inaba ◽

Shiro Suetsugu

Keyword(s):

Fatty Acid ◽

Lipid Composition ◽

Lipid Membranes ◽

Lipid Membrane ◽

Membrane Lipids ◽

Cell Types ◽

Cellular Lipid ◽

Head Groups ◽

Packing Defects ◽

Membrane Bending

Lipid compositions of cells differ according to cell types and intracellular organelles. Phospholipids are major cell membrane lipids and have hydrophilic head groups and hydrophobic fatty acid tails. The cellular lipid membrane without any protein adapts to spherical shapes, and protein binding to the membrane is thought to be required for shaping the membrane for various cellular events. Until recently, modulation of cellular lipid membranes was initially shown to be mediated by proteins recognizing lipid head groups, including the negatively charged ones of phosphatidylserine and phosphoinositides. Recent studies have shown that the abilities of membrane-deforming proteins are also regulated by the composition of fatty acid tails, which cause different degrees of packing defects. The binding of proteins to cellular lipid membranes is affected by the packing defects, presumably through modulation of their interactions with hydrophobic amino acid residues. Therefore, lipid composition can be characterized by both packing defects and charge density. The lipid composition regarding fatty acid tails affects membrane bending via the proteins with amphipathic helices, including those with the ArfGAP1 lipid packing sensor (ALPS) motif and via membrane-deforming proteins with structural folding, including those with the Bin–Amphiphysin–Rvs167 (BAR) domains. This review focuses on how the fatty acid tails, in combination with the head groups of phospholipids, affect protein-mediated membrane deformation.

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Effects of Lipid Membrane Curvature on Lipid Packing State Evaluated by Isothermal Titration Calorimetry

Langmuir ◽

10.1021/la304532k ◽

2013 ◽

Vol 29 (3) ◽

pp. 857-860 ◽

Cited By ~ 11

Author(s):

Hirokazu Yokoyama ◽

Keisuke Ikeda ◽

Masaki Wakabayashi ◽

Yasushi Ishihama ◽

Minoru Nakano

Keyword(s):

Isothermal Titration Calorimetry ◽

Lipid Membrane ◽

Membrane Curvature ◽

Titration Calorimetry ◽

Lipid Packing

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Influenza A matrix protein M1 induces lipid membrane deformation via protein multimerization

Bioscience Reports ◽

10.1042/bsr20191024 ◽

2019 ◽

Vol 39 (8) ◽

Cited By ~ 4

Author(s):

Ismail Dahmani ◽

Kai Ludwig ◽

Salvatore Chiantia

Keyword(s):

Influenza A ◽

Matrix Protein ◽

Lipid Membrane ◽

Membrane Curvature ◽

Correlation Spectroscopy ◽

Dimensional Structure ◽

Membrane Deformation ◽

Induced Membrane ◽

Cellular Models ◽

Matrix Protein M1

Abstract The matrix protein M1 of the Influenza A virus (IAV) is supposed to mediate viral assembly and budding at the plasma membrane (PM) of infected cells. In order for a new viral particle to form, the PM lipid bilayer has to bend into a vesicle toward the extracellular side. Studies in cellular models have proposed that different viral proteins might be responsible for inducing membrane curvature in this context (including M1), but a clear consensus has not been reached. In the present study, we use a combination of fluorescence microscopy, cryogenic transmission electron microscopy (cryo-TEM), cryo-electron tomography (cryo-ET) and scanning fluorescence correlation spectroscopy (sFCS) to investigate M1-induced membrane deformation in biophysical models of the PM. Our results indicate that M1 is indeed able to cause membrane curvature in lipid bilayers containing negatively charged lipids, in the absence of other viral components. Furthermore, we prove that protein binding is not sufficient to induce membrane restructuring. Rather, it appears that stable M1–M1 interactions and multimer formation are required in order to alter the bilayer three-dimensional structure, through the formation of a protein scaffold. Finally, our results suggest that, in a physiological context, M1-induced membrane deformation might be modulated by the initial bilayer curvature and the lateral organization of membrane components (i.e. the presence of lipid domains).

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Influenza A matrix protein M1 is sufficient to induce lipid membrane deformation

10.1101/565952 ◽

2019 ◽

Author(s):

Ismail Dahmani ◽

Kai Ludwig ◽

Salvatore Chiantia

Keyword(s):

Influenza A ◽

Matrix Protein ◽

Lipid Membrane ◽

Membrane Curvature ◽

Correlation Spectroscopy ◽

Dimensional Structure ◽

Membrane Deformation ◽

Induced Membrane ◽

Cellular Models ◽

Matrix Protein M1

AbstractThe matrix protein M1 of the Influenza A virus is considered to mediate viral assembly and budding at the plasma membrane (PM) of infected cells. In order for a new viral particle to form, the PM lipid bilayer has to bend into a vesicle towards the extracellular side. Studies in cellular models have proposed that different viral proteins might be responsible for inducing membrane curvature in this context (including M1), but a clear consensus has not been reached. In this study, we use a combination of fluorescence microscopy, cryogenic transmission electron microscopy (cryo-TEM), cryo-electron tomography (cryo-ET) and scanning fluorescence correlation spectroscopy (sFCS) to investigate M1-induced membrane deformation in biophysical models of the PM. Our results indicate that M1 is indeed capable to cause membrane curvature in lipid bilayers containing negatively-charged lipids, in the absence of other viral components. Furthermore, we prove that simple protein binding is not sufficient to induce membrane restructuring. Rather, it appears that stable M1-M1 interactions and multimer formation are required in order to alter the bilayer three-dimensional structure, through the formation of a protein scaffold. Finally, our results suggest that, in a physiological context, M1-induced membrane deformation might be modulated by the initial bilayer curvature and the lateral organization of membrane components (i.e. the presence of lipid domains).

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