In Vitro Reconstitution of Rab GTPase-dependent Vesicle Clustering by the Yeast Lethal Giant Larvae/Tomosyn Homolog,Sro7

Intracellular traffic in yeast between the Golgi and the cell surface is mediated by vesicular carriers that tether and fuse in a fashion that depends on the function of the Rab GTPase, Sec4. Overexpression of either of two Sec4 effectors, Sro7 or Sec15, results in the formation of a cluster of post-Golgi vesicles within the cell. Here, we describe a novel assay that recapitulates post-Golgi vesicle clustering in vitro utilizing purified Sro7 and vesicles isolated from late secretory mutants. We show clustering in vitro closely replicates the in vivo clustering process as it is highly dependent on both Sro7 and GTP-Sec4. We also make use of this assay to characterize a novel mutant form of Sro7 that results in a protein that is specifically defective in vesicle clustering both in vivo and in vitro. We show that this mutation acts by effecting a conformational change in Sro7 from the closed to a more open structure. Our analysis demonstrates that the N-terminal propeller needs to be able to engage the C-terminal tail for vesicle clustering to occur. Consistent with this, we show that occupancy of the N terminus of Sro7 by the t-SNARE Sec9, which results in the open conformation of Sro7, also acts to inhibit vesicle cluster formation by Sro7. This suggests a model by which a conformational switch in Sro7 acts to coordinate Rab-mediated vesicle tethering with SNARE assembly by requiring a single conformational state for both of these processes to occur.     

Peptide anchoring spore coat assembly to the outer forespore membrane in Bacillus subtilis

Spore formation in Bacillus subtilis involves the formation of a thick, proteinaceous shell or coat that is assembled around a specialized membrane known as the outer forespore membrane. Here we present evidence that the assembling coat is tethered to the outer forespore membrane by a 26-amino-acid peptide called SpoVM, which is believed to form an amphipathic helix. We show that proper localization of SpoVM is dependent on SpolVA, a morphogenetic protein that forms the basement layer of the spore coat, and conversely, that proper localization of SpoIVA is dependent on SpoVM. Genetic, biochemical and cytological evidence indicates that this mutual dependence is mediated in part by contact between an amino acid side-chain located near the extreme C-terminus of SpoIVA and an amino acid side-chain on the hydrophilic face of the SpoVM helix. Evidence is also presented that SpoVM adheres to the outer forespore membrane via hydrophobic, amino acid side-chains on the hydrophobic face of the helix. The results suggest that the SpoVM helix is oriented parallel to the membrane with the hydrophobic face buried in the lipid bilayer.     

Membrane-Elasticity Model of Coatless Vesicle Budding Induced by ESCRT Complexes

The formation of vesicles is essential for many biological processes, in particular for the trafficking of membrane proteins within cells. The Endosomal Sorting Complex Required for Transport (ESCRT) directs membrane budding away from the cytosol. Unlike other vesicle formation pathways, the ESCRT-mediated budding occurs without a protein coat. Here, we propose a minimal model of ESCRT-induced vesicle budding. Our model is based on recent experimental observations from direct fluorescence microscopy imaging that show ESCRT proteins colocalized only in the neck region of membrane buds. The model, cast in the framework of membrane elasticity theory, reproduces the experimentally observed vesicle morphologies with physically meaningful parameters. In this parameter range, the minimum energy configurations of the membrane are coatless buds with ESCRTs localized in the bud neck, consistent with experiment. The minimum energy configurations agree with those seen in the fluorescence images, with respect to both bud shapes and ESCRT protein localization. On the basis of our model, we identify distinct mechanistic pathways for the ESCRT-mediated budding process. The bud size is determined by membrane material parameters, explaining the narrow yet different bud size distributions in vitro and in vivo. Our membrane elasticity model thus sheds light on the energetics and possible mechanisms of ESCRT-induced membrane budding.     

Physical aspects of COPI vesicle formation

Abstract

Coat proteins orchestrate membrane budding and molecular sorting during the formation of transport intermediates. Coat protein complex I (COPI) vesicles shuttle between the Golgi apparatus and the endoplasmic reticulum and between Golgi stacks. The formation of a COPI vesicle proceeds in four steps: coat self-assembly, membrane deformation into a bud, fission of the coated vesicle and final disassembly of the coat to ensure recycling of coat components. Although some issues are still actively debated, the molecular mechanisms of COPI vesicle formation are now fairly well understood. In this review, we argue that physical parameters are critical regulators of COPI vesicle formation. We focus on recent real-time in vitro assays highlighting the role of membrane tension, membrane composition, membrane curvature and lipid packing in membrane remodelling and fission by the COPI coat.     

Association of the Yeast RNA-binding Protein She2p with the Tubular Endoplasmic Reticulum Depends on Membrane Curvature

Localization of mRNAs contributes to the generation and maintenance of cellular asymmetry in a wide range of organisms. In Saccharomyces cerevisiae, the so-called locasome complex with its core components Myo4p, She2p, and She3p localizes more than 30 mRNAs to the yeast bud tip. A significant fraction of these mRNAs encodes membrane or secreted proteins. Their localization requires, besides the locasome, a functional segregation apparatus of the cortical endoplasmic reticulum (ER), including the machinery that is involved in the movement of ER tubules into the bud. Colocalization of RNA-containing particles with these tubules suggests a coordinated transport of localized mRNAs and the cortical ER to the bud. Association of localized mRNAs to the ER requires the presence of the locasome component She2p. Here we report that She2p is not only an RNA-binding protein but can specifically bind to ER-derived membranes in a membrane curvature-dependent manner in vitro. Although it does not contain any known curvature recognizing motifs, the protein shows a binding preference for liposomes with a diameter resembling that of yeast ER tubules. In addition, membrane binding depends on tetramerization of She2p. In an in vivo membrane-tethering assay, She2p can target a viral peptide GFP fusion protein to the cortical ER, indicating that a fraction of She2p associates with the ER in vivo. Combining RNA- and membrane-binding features makes She2p an ideal coordinator of ER tubule and mRNA cotransport.     

Versatile Membrane Deformation Potential of Activated Pacsin

Endocytosis is a fundamental process in signaling and membrane trafficking. The formation of vesicles at the plasma membrane is mediated by the G protein dynamin that catalyzes the final fission step, the actin cytoskeleton, and proteins that sense or induce membrane curvature. One such protein, the F-BAR domain-containing protein pacsin, contributes to this process and has been shown to induce a spectrum of membrane morphologies, including tubules and tube constrictions in vitro. Full-length pacsin isoform 1 (pacsin-1) has reduced activity compared to its isolated F-BAR domain, implicating an inhibitory role for its C-terminal Src homology 3 (SH3) domain. Here we show that the autoinhibitory, intramolecular interactions in pacsin-1 can be released upon binding to the entire proline-rich domain (PRD) of dynamin-1, resulting in potent membrane deformation activity that is distinct from the isolated F-BAR domain. Most strikingly, we observe the generation of small, homogenous vesicles with the activated protein complex under certain experimental conditions. In addition, liposomes prepared with different methods yield distinct membrane deformation morphologies of BAR domain proteins and apparent activation barriers to pacsin-1''s activity. Theoretical free energy calculations suggest bimodality of the protein-membrane system as a possible source for the different outcomes, which could account for the coexistence of energetically equivalent membrane structures induced by BAR domain-containing proteins in vitro. Taken together, our results suggest a versatile role for pacsin-1 in sculpting cellular membranes that is likely dependent both on protein structure and membrane properties.     

Structural and functional studies on an FtsH inhibitor from Bacillus subtilis

The small 3 kDa SpoVM protein is essential for development of the spore in Bacillus subtilis. Genetic and biochemical experiments have shown that the function of SpoVM is to inhibit the proteolytic activity of FtsH during sporulation. We have used a combination of genetic and biophysical techniques to characterise the role of this small polypeptide. SpoVM was found to be widespread in Bacillus as well as in two Clostridia species, suggesting that SpoVM provides a common mechanism for inactivating the FtsH protease during spore differentiation. Using site-specific mutagenesis, we have identified C-terminal residues of SpoVM essential for biological activity. Analysis of SpoVM’s structure showed that it is able to assume an α-helical conformation in the presence of a lipid interface which may be important in interacting with FtsH.     

A unifying mechanism accounts for sensing of membrane curvature by BAR domains,amphipathic helices and membrane-anchored proteins

The discovery of proteins that recognize membrane curvature created a paradigm shift by suggesting that membrane shape may act as a cue for protein localization that is independent of lipid or protein composition. Here we review recent data on membrane curvature sensing by three structurally unrelated motifs: BAR domains, amphipathic helices and membrane-anchored proteins. We discuss the conclusion that the curvature of the BAR dimer is not responsible for sensing and that the sensing properties of all three motifs can be rationalized by the physicochemical properties of the curved membrane itself. We thus anticipate that membrane curvature will promote the redistribution of proteins that are anchored in membranes through any type of hydrophobic moiety, a thesis that broadens tremendously the implications of membrane curvature for protein sorting, trafficking and signaling in cell biology.     

Annexin V and vesicle membrane electroporation

The method of membrane electroporation (ME) has been used as an analytical tool to quantify the effect of membrane curvature on transient electric pore for-mation, and on the adsorption of the protein annexin V (M_r = 35,800) to the outer surface of unilamellar lipid vesicles (of radii 25 ≤ a/nm ≤ 200). Relaxation kinetic studies using optical membrane probes of the diphenylhexatriene type suggest that electric pore formation is induced by ionic interfacial polarization causing entrance of the (more polarizable) water into the lipid bilayer membrane yielding (hydrophobic and hydrophilic) pore states with a mean stationary pore radius r_p=0.35 (±0.05) nm. Extent and rate of ME, compared at the same induced transmembrane voltage, were found to decrease both with increasing vesicle radius and with increasing protein concentration. This `inhibitory' effect of annexin V is apparently allosteric and saturates at about [AN_T]_sat = 4 μm annexin V for vesicles of a = 100 nm at 1 mm total lipid concentration, 0.13 mm total Ca²⁺ concentration and at T = 293 K. Data analysis in terms of Gibbs area-difference-elasticity energy suggests that the bound annexin V reduces the gradient of the lateral pressure across the membrane. At [AN_T]_sat, about 20% of the vesicle surface is covered by the bound protein, but it is only 0.01% of the surface of the outer lipid leaflet in which a part of the protein, perhaps the aromatic residue of the tryptophan (W 187), is inserted. Insertion leads to a denser packing of the lipid molecules in the outer membrane leaflet. As a consequence, the radius of the electropores in the remaining membrane part, not covered by annexin V decreases (r_p/nm = 0.37, 0.36 and 0.27) with increasing adsorption of the protein ([AN_T] = 0, 2 and 4 μm, respectively). Received: 9 January 1997 / Accepted: 21 April 1997     

Lipidation of the autophagy proteins LC3 and GABARAP is a membrane-curvature dependent process

The phagophore membrane is highly curved along the rim of the open cup, suggesting that the molecular mechanisms governing its formation and growth could rely on membrane curvature-dependent events. To this end, we recently reported that lipidation of the LC3 protein family is facilitated on highly curved membranes in vitro. We further showed that the conjugating enzyme ATG3 contains an amphipathic helix that is responsible for this membrane curvature dependency, and that the maintenance of this amphipathic structure is essential for ATG3 function in vivo.     

Lipidation of the autophagy proteins LC3 and GABARAP is a membrane-curvature dependent process

The phagophore membrane is highly curved along the rim of the open cup, suggesting that the molecular mechanisms governing its formation and growth could rely on membrane curvature-dependent events. To this end, we recently reported that lipidation of the LC3 protein family is facilitated on highly curved membranes in vitro. We further showed that the conjugating enzyme ATG3 contains an amphipathic helix that is responsible for this membrane curvature dependency, and that the maintenance of this amphipathic structure is essential for ATG3 function in vivo.     

ARFGAP2 and ARFGAP3 Are Essential for COPI Coat Assembly on the Golgi Membrane of Living Cells

Coat protein complex I (COPI) vesicles play a central role in the recycling of proteins in the early secretory pathway and transport of proteins within the Golgi stack. Vesicle formation is initiated by the exchange of GDP for GTP on ARF1 (ADP-ribosylation factor 1), which, in turn, recruits the coat protein coatomer to the membrane for selection of cargo and membrane deformation. ARFGAP1 (ARF1 GTPase-activating protein 1) regulates the dynamic cycling of ARF1 on the membrane that results in both cargo concentration and uncoating for the generation of a fusion-competent vesicle. Two human orthologues of the yeast ARFGAP Glo3p, termed ARFGAP2 and ARFGAP3, have been demonstrated to be present on COPI vesicles generated in vitro in the presence of guanosine 5′-3-O-(thio)triphosphate. Here, we investigate the function of these two proteins in living cells and compare it with that of ARFGAP1. We find that ARFGAP2 and ARFGAP3 follow the dynamic behavior of coatomer upon stimulation of vesicle budding in vivo more closely than does ARFGAP1. Electron microscopy of ARFGAP2 and ARFGAP3 knockdowns indicated Golgi unstacking and cisternal shortening similarly to conditions where vesicle uncoating was blocked. Furthermore, the knockdown of both ARFGAP2 and ARFGAP3 prevents proper assembly of the COPI coat lattice for which ARFGAP1 does not seem to play a major role. This suggests that ARFGAP2 and ARFGAP3 are key components of the COPI coat lattice and are necessary for proper vesicle formation.     

Association of the endosomal sorting complex ESCRT-II with the Vps20 subunit of ESCRT-III generates a curvature-sensitive complex capable of nucleating ESCRT-III filaments

The scission of membranes necessary for vesicle biogenesis and cytokinesis is mediated by cytoplasmic proteins, which include members of the ESCRT (endosomal sorting complex required for transport) machinery. During the formation of intralumenal vesicles that bud into multivesicular endosomes, the ESCRT-II complex initiates polymerization of ESCRT-III subunits essential for membrane fission. However, mechanisms underlying the spatial and temporal regulation of this process remain unclear. Here, we show that purified ESCRT-II binds to the ESCRT-III subunit Vps20 on chemically defined membranes in a curvature-dependent manner. Using a combination of liposome co-flotation assays, fluorescence-based liposome interaction studies, and high-resolution atomic force microscopy, we found that the interaction between ESCRT-II and Vps20 decreases the affinity of ESCRT-II for flat lipid bilayers. We additionally demonstrate that ESCRT-II and Vps20 nucleate flexible filaments of Vps32 that polymerize specifically along highly curved membranes as a single string of monomers. Strikingly, Vps32 filaments are shown to modulate membrane dynamics in vitro, a prerequisite for membrane scission events in cells. We propose that a curvature-dependent assembly pathway provides the spatial regulation of ESCRT-III to fuse juxtaposed bilayers of elevated curvature.     

Modulation of membrane rigidity by the human vesicle trafficking proteins Sar1A and Sar1B

The sculpting of membranes into highly curved vesicles is central to intracellular cargo trafficking, yet the mechanical activities of trafficking proteins remain poorly understood. Using an optical trap based assay that measures in vitro membrane response to imposed deformations, we examined the behavior of the two human paralogs of Sar1, a key component of the COPII family of vesicle coat proteins. Like their yeast counterpart, the human Sar1 proteins can lower the mechanical rigidity of the membranes to which they bind. Unlike the yeast Sar1, the rigidity is not a monotonically decreasing function of concentration. At high concentrations, we find increased bending rigidity and decreased protein mobility. These features imply a model in which protein clustering governs membrane mechanical properties.     

Lipid Clustering Correlates with Membrane Curvature as Revealed by Molecular Simulations of Complex Lipid Bilayers

Cell membranes are complex multicomponent systems, which are highly heterogeneous in the lipid distribution and composition. To date, most molecular simulations have focussed on relatively simple lipid compositions, helping to inform our understanding of in vitro experimental studies. Here we describe on simulations of complex asymmetric plasma membrane model, which contains seven different lipids species including the glycolipid GM3 in the outer leaflet and the anionic lipid, phosphatidylinositol 4,5-bisphophate (PIP₂), in the inner leaflet. Plasma membrane models consisting of 1500 lipids and resembling the in vivo composition were constructed and simulations were run for 5 µs. In these simulations the most striking feature was the formation of nano-clusters of GM3 within the outer leaflet. In simulations of protein interactions within a plasma membrane model, GM3, PIP₂, and cholesterol all formed favorable interactions with the model α-helical protein. A larger scale simulation of a model plasma membrane containing 6000 lipid molecules revealed correlations between curvature of the bilayer surface and clustering of lipid molecules. In particular, the concave (when viewed from the extracellular side) regions of the bilayer surface were locally enriched in GM3. In summary, these simulations explore the nanoscale dynamics of model bilayers which mimic the in vivo lipid composition of mammalian plasma membranes, revealing emergent nanoscale membrane organization which may be coupled both to fluctuations in local membrane geometry and to interactions with proteins.     

Membrane curvature affects the stability and folding kinetics of bacteriorhodopsin

Biological membrane is crucial for the function, stability and folding of membrane proteins. By studying the stability and folding kinetics of bacteriorhodopsin (bR) in lipid vesicles with different sizes, here we report the influence of membrane curvature (vesicle size) on the stability and folding kinetics of bR. The results show that both the stability and folding kinetics of bR can be significantly changed when reconstituted into mimic membranes with different curvatures. The stability of bR decreases and unfolding rate of bR increases with the growth of vesicle size, i.e. decrease of membrane curvature. Our results suggest that it is possible to regulate the properties of membrane proteins by changing the curvature of membranes.     

Membrane Curvature Induction and Tubulation Are Common Features of Synucleins and Apolipoproteins

Synucleins and apolipoproteins have been implicated in a number of membrane and lipid trafficking events. Lipid interaction for both types of proteins is mediated by 11 amino acid repeats that form amphipathic helices. This similarity suggests that synucleins and apolipoproteins might have comparable effects on lipid membranes, but this has not been shown directly. Here, we find that α-synuclein, β-synuclein, and apolipoprotein A-1 have the conserved functional ability to induce membrane curvature and to convert large vesicles into highly curved membrane tubules and vesicles. The resulting structures are morphologically similar to those generated by amphiphysin, a curvature-inducing protein involved in endocytosis. Unlike amphiphysin, however, synucleins and apolipoproteins do not require any scaffolding domains and curvature induction is mediated by the membrane insertion and wedging of amphipathic helices alone. Moreover, we frequently observed that α-synuclein caused membrane structures that had the appearance of nascent budding vesicles. The ability to function as a minimal machinery for vesicle budding agrees well with recent findings that α-synuclein plays a role in vesicle trafficking and enhances endocytosis. Induction of membrane curvature must be under strict regulation in vivo; however, as we find it can also cause disruption of membrane integrity. Because the degree of membrane curvature induction depends on the concerted action of multiple proteins, controlling the local protein density of tubulating proteins may be important. How cellular safeguarding mechanisms prevent such potentially toxic events and whether they go awry in disease remains to be determined.     

The First N-terminal Amino Acids of α-Synuclein Are Essential for α-Helical Structure Formation In Vitro and Membrane Binding in Yeast

α-Synuclein (α-syn), a protein implicated in Parkinson's disease, is structurally diverse. In addition to its random-coil state, α-syn can adopt an α-helical structure upon lipid membrane binding or a β-sheet structure upon aggregation. We used yeast biology and in vitro biochemistry to detect how sequence changes alter the structural propensity of α-syn. The N-terminus of the protein, which adopts an α-helical conformation upon lipid binding, is essential for membrane binding in yeast, and variants that are more prone to forming an α-helical structure in vitro are generally more toxic to yeast. β-Sheet structure and inclusion formation, on the other hand, appear to be protective, possibly by sequestering the protein from the membrane. Surprisingly, sequential deletion of residues 2 through 11 caused a dramatic drop in α-helical propensity, vesicle binding in vitro, and membrane binding and toxicity in yeast, part of which could be mimicked by mutating aspartic acid at position 2 to alanine. Variants with distinct structural preferences, identified here by a reductionist approach, provide valuable tools for elucidating the nature of toxic forms of α-syn in neurons.     

Intermembrane docking reactions are regulated by membrane curvature

The polymorphism of eukaryotic cellular membranes is a tightly regulated and well-conserved phenotype. Recent data have revealed important regulatory roles of membrane curvature on the spatio-temporal localization of proteins and in membrane fusion. Here we quantified the influence of membrane curvature on the efficiency of intermembrane docking reactions. Using fluorescence microscopy, we monitored the docking of single vesicle–vesicle pairs of different diameter (30–200 nm) and therefore curvature, as mediated by neuronal soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs) and streptavidin-biotin. Surprisingly, the intermembrane docking efficiency exhibited an ∼30–60 fold enhancement as a function of curvature. In comparison, synaptotagmin and calcium accelerate SNARE-mediated fusion in vitro by a factor of 2–10. To explain this finding, we formulated a biophysical model. On the basis of our findings, we propose that membrane curvature can regulate intermembrane tethering reactions and consequently any downstream process, including the fusion of vesicles and possibly viruses with their target membranes.