Dynamic Shape Modulationof Deflated and Adhered LipidVesicles

The epsin N-terminal homology domain (ENTH) is a major player in clathrin-mediated endocytosis. To investigate the influence of initial membrane tension on ENTH binding and activity, we established a bilayer system based on adhered giant unilamellar vesicles (GUVs) to be able to control and adjust the membrane tension σ covering a broad regime. The shape of each individual adhered GUV as well as its adhesion area was monitored by spinning disc confocal laser microscopy. Control of σ in a range of 0.08-1.02 mN/m was achieved by altering the Mg(2+) concentration in solution, which changes the surface adhesion energy per unit area of the GUVs. Specific binding of ENTH to phosphatidylinositol 4,5-bisphosphate leads to a substantial increase in adhesion area of the sessile GUV. At low tension (<0.1 mN/m) binding of ENTH can induce tubular structures, whereas at higher membrane tension the ENTH interaction deflates the sessile GUV and thereby increases the adhesion area. The increase in adhesion area is mainly attributed to a decrease in the area compressibility modulus KA We propose that the insertion of the ENTH helix-0 into the membrane is largely responsible for the observed decrease in KA, which is supported by the observation that the mutant ENTH L6E shows a reduced increase in adhesion area. These results demonstrate that even in the absence of tubule formation, the area compressibility modulus and, as such, the bending rigidity of the membrane is considerably reduced upon ENTH binding. This renders membrane bending and tubule formation energetically less costly.

Studying how the membrane modulates ion channel and transporter activity is challenging because cells actively regulate membrane properties, whereas existing in vitro systems have limitations, such as residual solvent and unphysiologically high membrane tension. Cell-sized giant unilamellar vesicles (GUVs) would be ideal for in vitro electrophysiology, but efforts to measure the membrane current of intact GUVs have been unsuccessful. In this work, two challenges for obtaining the "whole-GUV" patch-clamp configuration were identified and resolved. First, unless the patch pipette and GUV pressures are precisely matched in the GUV-attached configuration, breaking the patch membrane also ruptures the GUV. Second, GUVs shrink irreversibly because the membrane/glass adhesion creating the high-resistance seal (>1 GΩ) continuously pulls membrane into the pipette. In contrast, for cell-derived giant plasma membrane vesicles (GPMVs), breaking the patch membrane allows the GPMV contents to passivate the pipette surface, thereby dynamically blocking membrane spreading in the whole-GMPV mode. To mimic this dynamic passivation mechanism, beta-casein was encapsulated into GUVs, yielding a stable, high-resistance, whole-GUV configuration for a range of membrane compositions. Specific membrane capacitance measurements confirmed that the membranes were truly solvent-free and that membrane tension could be controlled over a physiological range. Finally, the potential for ion transport studies was tested using the model ion channel, gramicidin, and voltage-clamp fluorometry measurements were performed with a voltage-dependent fluorophore/quencher pair. Whole-GUV patch-clamping allows ion transport and other voltage-dependent processes to be studied while controlling membrane composition, tension, and shape.

Osmotic pressure (Π) induces membrane tension in cell membranes and the lipid bilayers of vesicles and plays an important role in the functions and physical properties of these membranes. We recently developed a method to determine quantitatively the membrane tension of giant unilamellar vesicles (GUVs) under Π and applied it to GUVs comprising electrically neutral dioleoylphosphatidylcholine (DOPC). Here, we examined the effect of Π on GUVs composed of DOPC and negatively charged dioleoylphosphatidylglycerol (DOPG) in a buffer containing a physiological concentration of ions. First, we examined the rate constant, kr, for constant tension (σex)-induced rupture of DOPG/DOPC (4/6)-GUVs under Π and obtained the dependence of kr on σex in GUVs for various values of Π. Comparing this dependence in the absence of Π provided values for membrane tension due to Π, σosm, which agree with the theoretical values within the experimental error. The values of σosm for DOPG/DOPC-GUVs were smaller than those for DOPC-GUVs under the same Π. Two factors, that is, the solute concentration in a GUV suspension and the elastic modulus of the GUV membrane, can reasonably explain this difference based on the theory of σosm. We also examined the effect of Π on the rate constant, kFF, for the transbilayer movement of lipid molecules in single GUVs. The values of kFF increased with increasing Π, indicating that kFF increased with σosm. This result supports the existence of prepores in stretched lipid bilayers. Based on these results, we discuss the membrane tension of DOPG/DOPC-GUVs under Π.

During endocytosis, membrane remodeling of a planar membrane into a highly curved vesicle is controlled by a complex protein machinery. However, the regulatory role of physical properties such as membrane tension is highly debated. At the beginning of the formation of a vesicle during clathrin mediated endocytosis, the protein epsin binds to its receptor lipid phosphatidylinositol-4,5-bisphosphate (PIP₂). Upon binding, a previously unstructured part of the epsin N-terminal homology domain (ENTH) forms an &#945;-helix, which inserts into the membrane. Experiments using artificial lipid bilayers were performed to study the interaction of ENTH and lipid bilayers as a function of lipid composition and membrane tension. The binding affinity of ENTH to PIP₂ was analyzed for different lipid compositions and membrane topologies. Similar affinities of ENTH binding to PIP₂ in the high nanomolar range were measured, independent of the used lipid composition and membrane topology investigated. Protruded pore-spanning membranes were established to investigate the remodeling activity of ENTH as a function of lipid composition. Binding of ENTH to membranes having a large area compressibility modulus and a high lysis tension resulted in growth of the membrane protrusions. Binding of ENTH to membranes with a lower area compressibility modulus and lysis tension resulted in the formation of membrane defects. For all lipid compositions analyzed, no vesiculation or tubulation was observed after binding of ENTH. To analyze whether the high membrane tension of the protruded pore-spanning membranes suppresses any membrane remodeling ability of ENTH, experiments with giant unilamellar vesicles adhering to a solid support were conducted. The vesicles’ adhesion strength and lateral tension was adjusted to analyze the ENTH’s remodeling ability at lateral tensions corresponding to low and high membrane tensions found in cells. The formation of membrane tubes was observed for vesicles having a low membrane tension. Increasing the membrane tension resulted in a suppression of tube formation. Independent of the membrane tension, flattening of the vesicles was monitored after binding of ENTH. The inserted ENTH helix disturbs lipid packing, which reduces the area compressibility modulus and thus the bending rigidity of the membranes. The reduced bending rigidity lowers the energy required for the generation of membrane curvature. As the inserted helix of ENTH also splays the lipid head groups, thereby inducing local curvature, the combination of both mechanisms is expected to efficiently initiate the formation of a vesicle during clathrin mediated endocytosis.

Effect of membrane tension on (-)-epigallocatechin gallate-induced burst of single giant unilamellar vesicles.

Synaptic vesicles fuse with the plasma membrane in response to Ca(2+) influx, thereby releasing neurotransmitters into the synaptic cleft. The protein machinery that mediates this process, consisting of soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs) and regulatory proteins, is well known, but the mechanisms by which these proteins prime synaptic membranes for fusion are debated. In this study, we applied large-scale, automated cryo-electron tomography to image an in vitro system that reconstitutes synaptic fusion. Our findings suggest that upon docking and priming of vesicles for fast Ca(2)(+)-triggered fusion, SNARE proteins act in concert with regulatory proteins to induce a local protrusion in the plasma membrane, directed towards the primed vesicle. The SNAREs and regulatory proteins thereby stabilize the membrane in a high-energy state from which the activation energy for fusion is profoundly reduced, allowing synchronous and instantaneous fusion upon release of the complexin clamp.

Membrane-tension-dominated growth mechanism and size modulation of giant unilamellar vesicles in electroformation

Sorting of membrane proteins within the secretory pathway of eukaryotic cells is a complex process involving discrete sorting signals as well as physico-chemical properties of the transmembrane domain (TMD). Previous work demonstrated that tail-anchored (TA) protein sorting at the interface between the Endoplasmic Reticulum (ER) and the Golgi complex is exquisitely dependent on the length and hydrophobicity of the transmembrane domain, and suggested that an imbalance between TMD length and bilayer thickness (hydrophobic mismatch) could drive long TMD-containing proteins into curved membrane domains, including ER exit sites, with consequent export of the mismatched protein out of the ER. Here, we tested a possible role of curvature in TMD-dependent sorting in a model system consisting of Giant Unilamellar Vesicles (GUVs) from which narrow membrane tubes were pulled by micromanipulation. Fluorescent TA proteins differing in TMD length were incorporated into GUVs of uniform lipid composition or made of total ER lipids, and TMD-dependent sorting and diffusion, as well as the bending rigidity of bilayers made of microsomal lipids, were investigated. Long and short TMD-containing constructs were inserted with similar orientation, diffused equally rapidly in GUVs and in tubes pulled from GUVs, and no difference in their final distribution between planar and curved regions was detected. These results indicate that curvature alone is not sufficient to drive TMD-dependent sorting at the ER-Golgi interface, and set the basis for the investigation of the additional factors that must be required.

Adhesion-Induced Domain Formation in Multicomponent Membranes

Biomimetic microscale platforms for the visualization of biological processes : from GUVs towards artificial cells

Mimicking Cell Pinocytosis: Lipid Vesicles Engulfment of Oil-in-Water Droplets

Protein-Induced Membrane Shape Instability: Dynamics and Membrane Tension Dependence

Understanding and manipulating the interactions between foreign bodies and cell membranes during endo- and phagocytosis is of paramount importance, not only for the fate of living cells but also for numerous biomedical applications. This study aims to elucidate the role of variables such as anisotropic particle shape, curvature, orientation, membrane tension, and adhesive strength in this essential process using a minimal experimental biomimetic system comprising giant unilamellar vesicles and rod-like particles with different curvatures and aspect ratios. We find that the particle wrapping process is dictated by the balance between the elastic free energy penalty and adhesion free energy gain, leading to two distinct engulfment pathways, tip-first and side-first, emphasizing the significance of the particle orientation in determining the pathway. Moreover, our experimental results are consistent with theoretical predictions in a state diagram, showcasing how to control the wrapping pathway from surfing to partial to complete wrapping by the interplay between membrane tension and adhesive strength. At moderate particle concentrations, we observed the formation of rod clusters, which exhibited cooperative and sequential wrapping. Our study contributes to a comprehensive understanding of the mechanistic intricacies of endocytosis by highlighting how the interplay between the anisotropic particle shape, curvature, orientation, membrane tension, and adhesive strength can influence the engulfment pathway.

Membrane Tension in Rapidly Moving Cells Is Determined by Cytoskeletal Forces

The reshaping of the cell membrane is an integral part of many cellular phenomena, such as endocytosis, trafficking, the formation of filopodia, etc. Many different proteins associate with curved membranes because of their ability to sense or induce membrane curvature. Typically, these processes involve a multitude of proteins making them too complex to study quantitatively in the cell. We describe a protocol to reconstitute a curved membrane in vitro, mimicking a curved cellular structure, such as the endocytic neck. A giant unilamellar vesicle (GUV) is used as a model of a cell membrane, whose internal pressure and surface tension are controlled with micropipette aspiration. Applying a point pulling force on the GUV using optical tweezers creates a nanotube of high curvature connected to a flat membrane. This method has traditionally been used to measure the fundamental mechanical properties of lipid membranes, such as bending rigidity. In recent years, it has been expanded to study how proteins interact with membrane curvature and the way they affect the shape and the mechanics of membranes. A system combining micromanipulation, microinjection, optical tweezers, and confocal microscopy allows measurement of membrane curvature, membrane tension, and the surface density of proteins, concurrently. From these measurements, many important mechanical and morphological properties of the protein-membrane system can be inferred. In addition, we lay out a protocol of creating GUVs in the presence of physiological salt concentration, and a method of quantifying the surface density of proteins on the membrane from fluorescence intensities of labeled proteins and lipids.