Your search keyword '"Carl C. Hayden"' showing total 16 results

1. Liquid-like protein interactions catalyse assembly of endocytic vesicles

Author

Eileen M. Lafer, Carl C. Hayden, J Blair Richter, Liping Wang, Kasey J. Day, Grace Kago, and Jeanne C. Stachowiak

Subjects

0303 health sciences, Budding, Vesicle budding, Chemistry, Vesicle, Cell Biology, Endocytosis, In vitro, Cell biology, Protein–protein interaction, 03 medical and health sciences, 0302 clinical medicine, Endocytic vesicle, Membrane, 030220 oncology & carcinogenesis, 030304 developmental biology

Abstract

During clathrin-mediated endocytosis, dozens of proteins assemble into an interconnected network at the plasma membrane. As initiators of endocytosis, Eps15 and Fcho1/2 concentrate downstream components, while permitting dynamic rearrangement within the budding vesicle. How do initiator proteins meet these competing demands? Here we show that Eps15 and Fcho1/2 rely on weak, liquid-like interactions to catalyse endocytosis. In vitro, these weak interactions promote the assembly of protein droplets with liquid-like properties. To probe the physiological role of these liquid-like networks, we tuned the strength of initiator protein assembly in real time using light-inducible oligomerization of Eps15. Low light levels drove liquid-like assemblies, restoring normal rates of endocytosis in mammalian Eps15-knockout cells. By contrast, initiator proteins formed solid-like assemblies upon exposure to higher light levels, which stalled vesicle budding, probably owing to insufficient molecular rearrangement. These findings suggest that liquid-like assembly of initiator proteins provides an optimal catalytic platform for endocytosis. Phase separation promotes clathrin-mediated endocytosis; Day et al. show that Eps15 and Fcho1 rely on weak, liquid-like interactions to efficiently catalyse endocytosis.

Published

2021

2. A Förster Resonance Energy Transfer-Based Sensor of Steric Pressure on Membrane Surfaces

Author

Carl C. Hayden, Jeanne C. Stachowiak, D. Thirumalai, and Justin R. Houser

Subjects

Steric effects, Fluorophore, Surface Properties, Vesicle, Lipid Bilayers, Biological membrane, General Chemistry, Biochemistry, Article, Catalysis, Membrane bending, Adaptor Proteins, Vesicular Transport, chemistry.chemical_compound, Colloid and Surface Chemistry, Membrane, Förster resonance energy transfer, Protein Domains, chemistry, Fluorescence Resonance Energy Transfer, Biophysics, Polymer physics, Fluorescent Dyes

Abstract

Cellular membranes are densely covered by proteins. Steric pressure generated by protein collisions plays a significant role in shaping and curving biological membranes. However, no method currently exists for measuring steric pressure at membrane surfaces. Here, we developed a sensor based on Förster resonance energy transfer (FRET), which uses the principles of polymer physics to precisely detect changes in steric pressure. The sensor consists of a polyethylene glycol chain tethered to the membrane surface. The polymer has a donor fluorophore at its free end, such that FRET with acceptor fluorophores in the membrane provides a real-time readout of polymer extension. As a demonstration of the sensor, we measured the steric pressure generated by a model protein involved in membrane bending, the N-terminal homology domain (ENTH) of Epsin1. As the membrane becomes crowded by ENTH proteins, the polymer chain extends, increasing the fluorescence lifetime of the donor. Drawing on polymer theory, we use this change in lifetime to calculate steric pressure as a function of membrane coverage by ENTH, validating theoretical equations of state. Further, we find that ENTH's ability to break up larger vesicles into smaller ones correlates with steric pressure rather than the chemistry used to attach ENTH to the membrane surface. This result addresses a long-standing question about the molecular mechanisms of membrane remodeling. More broadly, this sensor makes it possible to measure steric pressure in situ during diverse biochemical events that occur on membrane surfaces, such as membrane remodeling, ligand-receptor binding, assembly of protein complexes, and changes in membrane organization.

Published

2020

3. Liposome-Mediated Chemotherapeutic Delivery Is Synergistically Enhanced by Ternary Lipid Compositions and Cationic Lipids

Author

Carl C. Hayden, Zachary I. Imam, Jeanne C. Stachowiak, Morgan Mendicino, and Andrea N. Trementozzi

Subjects

Drug, Surface Properties, media_common.quotation_subject, Cell, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Propane, Electrochemistry, medicine, General Materials Science, Doxorubicin, Lipid bilayer, Spectroscopy, media_common, Liposome, Chemistry, Cationic polymerization, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Small molecule, 0104 chemical sciences, medicine.anatomical_structure, Membrane, Liposomes, Biophysics, 0210 nano-technology, medicine.drug

Abstract

Most small molecule chemotherapeutics must cross one or more cellular membrane barriers to reach their biochemical targets. Owing to the relatively low solubility of chemotherapeutics in the lipid membrane environment, high doses are often required to achieve a therapeutic effect. The resulting systemic toxicity has motivated efforts to improve the efficiency of chemotherapeutic delivery to the cellular interior. Toward this end, liposomes containing lipids with cationic head groups have been shown to permeabilize cellular membranes, resulting in the more efficient release of encapsulated drugs into the cytoplasm. However, the high concentrations of cationic lipids required to achieve efficient delivery remain a key limitation, frequently resulting in toxicity. Toward overcoming this limitation, here, we investigate the ability of ternary lipid mixtures to enhance liposomal delivery. Specifically, we investigate the delivery of the chemotherapeutic, doxorubicin, using ternary liposomes that are homogeneous at physiological temperature but have the potential to undergo membrane phase separation upon contact with the cell surface. This approach, which relies upon the ability of membrane phase boundaries to promote drug release, provides a novel method for reducing the overall concentration of cationic lipids required for efficient delivery. Our results show that this approach improves the performance of doxorubicin by up to 5-fold in comparison to the delivery of the same drug by conventional liposomes. These data demonstrate that ternary lipid compositions and cationic lipids can be combined synergistically to substantially improve the efficiency of chemotherapeutic delivery in vitro.

Published

2019

4. Clathrin senses membrane curvature

Author

Jeanne C. Stachowiak, Wade F. Zeno, Carl C. Hayden, Ajay S. Thatte, Eileen M. Lafer, Liping Wang, Avinash K. Gadok, and Jacob B. Hochfelder

Subjects

0303 health sciences, biology, Chemistry, New and Notable, Protein domain, Cell Membrane, Biophysics, Signal transducing adaptor protein, Endocytosis, Curvature, Clathrin coat, Clathrin, Cell Line, 03 medical and health sciences, Adaptor Proteins, Vesicular Transport, 0302 clinical medicine, Membrane, Membrane curvature, Synapses, biology.protein, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The ability of proteins to assemble at sites of high membrane curvature is essential to diverse membrane remodeling processes, including clathrin-mediated endocytosis. Multiple adaptor proteins within the clathrin pathway have been shown to sense regions of high membrane curvature, leading to local recruitment of the clathrin coat. Because clathrin triskelia do not bind to the membrane directly, it has remained unclear whether the clathrin coat plays an active role in sensing membrane curvature or is passively recruited by adaptor proteins. Using a synthetic tag to assemble clathrin directly on membrane surfaces, here we show that clathrin is a strong sensor of membrane curvature, comparable with previously studied adaptor proteins. Interestingly, this sensitivity arises from clathrin assembly rather than from the properties of unassembled triskelia, suggesting that triskelia have preferred angles of interaction, as predicted by earlier structural data. Furthermore, when clathrin is recruited by adaptors, its curvature sensitivity is amplified by 2- to 10-fold, such that the resulting protein complex is up to 100 times more likely to assemble on a highly curved surface compared with a flatter one. This exquisite sensitivity points to a synergistic relationship between the coat and its adaptor proteins, which enables clathrin to pinpoint sites of high membrane curvature, an essential step in ensuring robust membrane traffic. More broadly, these findings suggest that protein networks, rather than individual protein domains, are likely the most potent drivers of membrane curvature sensing.

Published

2020

5. Liquid-like protein interactions catalyze assembly of endocytic vesicles

Author

Liping Wang, Eileen M. Lafer, Kasey J. Day, Jeanne C. Stachowiak, J Blair Richter, Carl C. Hayden, and Grace Kago

Subjects

0303 health sciences, Vesicle budding, Budding, Chemistry, Vesicle, Endocytosis, Protein–protein interaction, 03 medical and health sciences, 0302 clinical medicine, Endocytic vesicle, Membrane, Biophysics, Membrane surface, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

During clathrin-mediated endocytosis, dozens of proteins assemble into an interconnected network at the plasma membrane. As early initiators of endocytosis, Eps15 and Fcho1 are responsible for locally concentrating downstream components on the membrane surface. However, they must also permit dynamic rearrangement of proteins within the budding vesicle. How do initiator proteins meet these competing demands? Here we show that Eps15 and Fcho1 rely on weak, liquid-like interactions to efficiently catalyze endocytosis. In reconstitution experiments, these weak interactions promote the assembly of protein droplets with liquid-like properties, including rapid coalescence and dynamic exchange of protein components. To probe the physiological role of liquid-like interactions among initiator proteins, we tuned the strength of initiator protein assembly in real time using light-inducible oligomerization of Eps15. Low light levels drove initiator proteins into liquid-like assemblies, restoring normal rates of endocytosis in mammalian Eps15 knockout cells. In contrast, initiator proteins formed solid-like assemblies upon exposure to higher light levels. Assembly of these structures stalled vesicle budding, likely owing to insufficient molecular rearrangement. These findings suggest that liquid-like assembly of early initiator proteins provides an optimal catalytic platform for endocytosis.

Published

2019

6. Clathrin Senses Membrane Curvature

Author

Jacob B. Hochfelder, Wade F. Zeno, Jeanne C. Stachowiak, Liping Wang, Carl C. Hayden, Eileen M. Lafer, Avinash K. Gadok, and Ajay S. Thatte

Subjects

Membrane, biology, Membrane curvature, Chemistry, Protein domain, biology.protein, Biophysics, Signal transducing adaptor protein, Curvature, Endocytosis, Clathrin, Clathrin coat

Abstract

The ability of proteins to sense membrane curvature is essential to diverse membrane remodeling processes including clathrin-mediated endocytosis. Multiple adaptor proteins within the clathrin pathway have been shown to assemble together at curved membrane sites, leading to local recruitment of the clathrin coat. Because clathrin does not bind to the membrane directly, it has remained unclear whether clathrin plays an active role in sensing curvature or is passively recruited by its adaptor proteins. Using a synthetic tag to assemble clathrin directly on membrane surfaces, here we show that clathrin is a strong sensor of membrane curvature, comparable to previously studied adaptor proteins. Interestingly, this sensitivity arises from clathrin assembly, rather than from the properties of unassembled triskelia, suggesting that triskelia have preferred angles of interaction, as predicted by earlier structural data. Further, when clathrin is recruited by adaptors, its curvature sensitivity is amplified by two to ten-fold, such that the resulting protein complex is up to 100 times more likely to assemble on a highly curved surface, compared to a flatter one. This exquisite sensitivity points to a synergistic relationship between the coat and its adaptor proteins, which enables clathrin to pinpoint sites of high membrane curvature, an essential step in ensuring robust membrane traffic. More broadly, these findings suggest that protein networks, rather than individual protein domains, are likely the critical drivers of membrane curvature sensing.

Published

2021

7. Membrane fission by protein crowding

Author

Eileen M. Lafer, Chi Zhao, Padmini Rangamani, Carl C. Hayden, Avinash K. Gadok, Wilton T. Snead, and Jeanne C. Stachowiak

Subjects

0301 basic medicine, Multidisciplinary, biology, Protein Conformation, Fission, Membrane transport protein, Cell Membrane, Intrinsically disordered proteins, Endocytosis, Rats, Cell biology, Adaptor Proteins, Vesicular Transport, 03 medical and health sciences, 030104 developmental biology, Membrane, Protein structure, PNAS Plus, Membrane fission, Membrane curvature, biology.protein, Animals, Hydrophobic and Hydrophilic Interactions, Membrane biophysics, Cytokinesis

Abstract

Membrane fission, which facilitates compartmentalization of biological processes into discrete, membrane-bound volumes, is essential for cellular life. Proteins with specific structural features including constricting rings, helical scaffolds, and hydrophobic membrane insertions are thought to be the primary drivers of fission. In contrast, here we report a mechanism of fission that is independent of protein structure-steric pressure among membrane-bound proteins. In particular, random collisions among crowded proteins generate substantial pressure, which if unbalanced on the opposite membrane surface can dramatically increase membrane curvature, leading to fission. Using the endocytic protein epsin1 N-terminal homology domain (ENTH), previously thought to drive fission by hydrophobic insertion, our results show that membrane coverage correlates equally with fission regardless of the hydrophobicity of insertions. Specifically, combining FRET-based measurements of membrane coverage with multiple, independent measurements of membrane vesiculation revealed that fission became spontaneous as steric pressure increased. Further, fission efficiency remained equally potent when helices were replaced by synthetic membrane-binding motifs. These data challenge the view that hydrophobic insertions drive membrane fission, suggesting instead that the role of insertions is to anchor proteins strongly to membrane surfaces, amplifying steric pressure. In line with these conclusions, even green fluorescent protein (GFP) was able to drive fission efficiently when bound to the membrane at high coverage. Our conclusions are further strengthened by the finding that intrinsically disordered proteins, which have large hydrodynamic radii yet lack a defined structure, drove fission with substantially greater potency than smaller, structured proteins.

Published

2017

8. Lipid Membrane Domains for the Selective Adsorption and Surface Patterning of Conjugated Polyelectrolytes

Author

Carl C. Hayden, Andrew P. Shreve, Atul N. Parikh, Nicole Zawada, Darryl Y. Sasaki, Sean F. Gilmore, Mari Angelica A. Sanchez, Jeanne C. Stachowiak, Prihatha Narasimmaraj, and Hsing-Lin Wang

Subjects

Quenching (fluorescence), Molecular Structure, Polymers, Surface Properties, Chemistry, Analytical chemistry, Surfaces and Interfaces, Condensed Matter Physics, Conjugated Polyelectrolytes, Electrolytes, Membrane Lipids, Membrane, Adsorption, Dynamic light scattering, Chemical engineering, Phase (matter), Selective adsorption, Electrochemistry, General Materials Science, Lipid bilayer, Spectroscopy

Abstract

Conjugated polyelectrolytes (CPEs) are promising materials for generating optoelectronics devices under environmentally friendly processing conditions, but challenges remain to develop methods to define lateral features for improved junction interfaces and direct optoelectronic pathways. We describe here the potential to use a bottom-up approach that employs self-assembly in lipid membranes to form structures to template the selective adsorption of CPEs. Phase separation of gel phase anionic lipids and fluid phase phosphocholine lipids allowed the formation of negatively charged domain assemblies that selectively adsorb a cationic conjugated polyelectrolyte (P2). Spectroscopic studies found the adsorption of P2 to negatively charged membranes resulted in minimal structural change of the solution phase polymer but yielded an enhancement in fluorescence intensity (~50%) due to loss of quenching pathways. Fluorescence microscopy, dynamic light scattering, and AFM imaging were used to characterize the polymer-membrane interaction and the polymer-bound domain structures of the biphasic membranes. In addition to randomly formed circular gel phase domains, we also show that predefined features, such as straight lines, can be directed to form upon etched patterns on the substrate, thus providing potential routes toward the self-organization of optoelectronic architectures.

Published

2013

9. Targeting Proteins to Liquid-Ordered Domains in Lipid Membranes

Author

James A. Voigt, Carl C. Hayden, Bruce C. Bunker, Darryl Y. Sasaki, Julia Wang, Mari Angelica A. Sanchez, and Jeanne C. Stachowiak

Subjects

1,2-Dipalmitoylphosphatidylcholine, Iminodiacetic acid, Stereochemistry, Vesicle, Proteins, Fluorescence correlation spectroscopy, Surfaces and Interfaces, Condensed Matter Physics, chemistry.chemical_compound, Cholesterol, Membrane, Models, Chemical, chemistry, Phosphatidylcholines, Electrochemistry, Biophysics, Membrane fluidity, lipids (amino acids, peptides, and proteins), General Materials Science, Target protein, Lipid bilayer, Unilamellar Liposomes, Spectroscopy, Histidine

Abstract

We demonstrate the construction of novel protein-lipid assemblies through the design of a lipid-like molecule, DPIDA, endowed with tail-driven affinity for specific lipid membrane phases and head-driven affinity for specific proteins. In studies performed on giant unilamellar vesicles (GUVs) with varying mole fractions of dipalymitoylphosphatidylcholine (DPPC), cholesterol, and diphytanoylphosphatidyl choline (DPhPC), DPIDA selectively partitioned into the more ordered phases, either solid or liquid-ordered (L(o)) depending on membrane composition. Fluorescence imaging established the phase behavior of the resulting quaternary lipid system. Fluorescence correlation spectroscopy confirmed the fluidity of the L(o) phase containing DPIDA. In the presence of CuCl(2), the iminodiacetic acid (IDA) headgroup of DPIDA forms the Cu(II)-IDA complex that exhibits a high affinity for histidine residues. His-tagged proteins were bound specifically to domains enriched in DPIDA, demonstrating the capacity to target protein binding selectively to both solid and L(o) phases. Steric pressure from the crowding of surface-bound proteins transformed the domains into tubules with persistence lengths that depended on the phase state of the lipid domains.

Published

2010

10. Lipid Nanotube Formation from Streptavidin−Membrane Binding

Author

Haiqing Liu, George D. Bachand, Darryl Y. Sasaki, Carl C. Hayden, Elisa Abate, and Hahkjoon Kim

Subjects

Streptavidin, Nanotubes, Vesicle fusion, Chemistry, Vesicle, Temperature, technology, industry, and agriculture, Analytical chemistry, Surfaces and Interfaces, Membrane budding, Condensed Matter Physics, Lipids, Phase Transition, chemistry.chemical_compound, Membrane, Isoelectric point, Biotinylation, Electrochemistry, Biophysics, lipids (amino acids, peptides, and proteins), General Materials Science, POPC, Spectroscopy

Abstract

A novel transformation of giant lipid vesicles to produce nanotubular structures was observed upon the binding of streptavidin to biotinylated membranes. Unlike membrane budding and tubulation processes caused by proteins involved with endocytosis and vesicle fusion, streptavidin is known to crystallize at near the isoelectric point (pI 5 to 6) into planar sheets against biotinylated films. We have found, however, that at neutral pH membranes of low bending rigidity (10kT), such as 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC), spontaneously produce tubular structures with widths ranging from micrometers to below the diffraction limit (250 nm) and lengths spanning up to hundreds of micrometers. The nanotubes were typically held taut between surface-bound vesicles suggesting high membrane tension, yet the lipid nanotubes exhibited a fluidic nature that enabled the transport of entrained vesicles. Confocal microscopy confirmed the uniform coating of streptavidin over the vesicles and nanotubes. Giant vesicles composed of lipid membranes of higher bending energy exhibited only aggregation in the presence of streptavidin. Routes toward the development of these highly curved membrane structures are discussed in terms of general protein-membrane interactions.

Published

2008

11. Intrinsically disordered proteins drive membrane curvature

Author

Jeanne C. Stachowiak, Justin R. Houser, David J. Busch, Carl C. Hayden, Eileen M. Lafer, and Michael B. Sherman

Subjects

Biophysics, General Physics and Astronomy, Intrinsically disordered proteins, General Biochemistry, Genetics and Molecular Biology, Article, Membrane bending, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Humans, Cell Shape, Cells, Cultured, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Chemistry, Cell Membrane, Signal transducing adaptor protein, Clathrin-Coated Vesicles, General Chemistry, Transmembrane protein, Cell biology, Protein Structure, Tertiary, Intrinsically Disordered Proteins, Adaptor Proteins, Vesicular Transport, Membrane, Membrane curvature, Monomeric Clathrin Assembly Proteins, Ap180, 030217 neurology & neurosurgery

Abstract

Assembly of highly curved membrane structures is essential to cellular physiology. The prevailing view has been that proteins with curvature-promoting structural motifs, such as wedge-like amphipathic helices and crescent-shaped BAR domains, are required for bending membranes. Here we report that intrinsically disordered domains of the endocytic adaptor proteins, Epsin1 and AP180 are highly potent drivers of membrane curvature. This result is unexpected since intrinsically disordered domains lack a well-defined three-dimensional structure. However, in vitro measurements of membrane curvature and protein diffusivity demonstrate that the large hydrodynamic radii of these domains generate steric pressure that drives membrane bending. When disordered adaptor domains are expressed as transmembrane cargo in mammalian cells, they are excluded from clathrin-coated pits. We propose that a balance of steric pressure on the two surfaces of the membrane drives this exclusion. These results provide quantitative evidence for the influence of steric pressure on the content and assembly of curved cellular membrane structures., Proteins that bend membranes often contain curvature-promoting structural motifs such as wedges or crescent-shaped domains. Busch et al. report that intrinsically disordered domains can also drive membrane curvature and provide evidence that steric pressure driven by protein crowding mediates this effect.

Published

2015

12. Towards understanding of Nipah virus attachment protein assembly and the role of protein affinity and crowding for membrane curvature events

Author

Jeanne C. Stachowiak, Carl C. Hayden, Darryl Y. Sasaki, Ryan Wesley Davis, and Oscar A. Negrete

Subjects

Cell membrane, medicine.anatomical_structure, Cell fusion, Membrane, Membrane curvature, Point mutation, Nipah virus, Cell, medicine, Biology, Receptor, Cell biology

Abstract

Pathogenic viruses are a primary threat to our national security and to the health and economy of our world. Effective defense strategies to combat viral infection and spread require the development of understanding of the mechanisms that these pathogens use to invade the host cell. We present in this report results of our research into viral particle recognition and fusion to cell membranes and the role that protein affinity and confinement in lipid domains plays in membrane curvature in cellular fusion and fission events. Herein, we describe 1) the assembly of the G attachment protein of Nipah virus using point mutation studies to define its role in viral particle fusion to the cell membrane, 2) how lateral pressure of membrane bound proteins induce curvature in model membrane systems, and 3) the role of membrane curvature in the selective partitioning of molecular receptors and specific affinity of associated proteins.

Published

2013

13. Protein-Protein Crowding as a Driving Force for Membrane Bending during Endocytosis

Author

Darryl Y. Sasaki, Christopher J. Ryan, Phillip L. Geissler, Eva M. Schmid, Hyoung Sook Ann, Jeanne C. Stachowiak, Daniel A. Fletcher, and Carl C. Hayden

Subjects

Membrane bending, Crystallography, Membrane, Epsin, Amphipathic Alpha Helix, Helix, Biophysics, Biology, Membrane transport, Transmembrane protein, Elasticity of cell membranes

Abstract

Highly curved membranes are essential to many cellular functions, motivating an intense effort to discover the mechanisms that shape them. A conserved feature among many proteins that participate in membrane bending is an amphipathic alpha helix that inserts into one membrane leaflet, attaching the protein to the membrane. These insertions are thought to bend membranes by pushing lipid heads apart like a wedge. First reported for the Epsin 1 N-terminal Homology (ENTH) domain, a protein believed to drive curvature during clathrin-mediated endocytosis, this mechanism is thought to shape a wide range of membrane structures, from trafficking vesicles to viral envelopes. However, recent computational studies have questioned the efficiency of the insertion mechanism, predicting that proteins with amphipathic helices must cover nearly 100% of the membrane surface to generate high curvature, an improbable situation given that cellular membranes are densely populated with a diversity of proteins. How then do proteins with amphipathic helices drive efficient bending of cellular membranes? We show that Epsin1 bends membranes via protein-protein crowding rather than via helix insertion. By correlating membrane tubule formation with FRET (Forster Resonance Energy Transfer) lifetime-based measurements of ENTH density on membrane surfaces, we demonstrate that protein coverage above ∼20% is sufficient to bend membranes. Whether proteins attach by inserting a helix or by binding lipid heads with an engineered tag, lateral steric pressure generated by bound proteins drives bending. Our results suggest that Epsin1's helix insertion functions primarily to achieve high protein-membrane affinity, enabling binding in a crowded environment. These findings call for a reexamination of the insertion hypothesis and demonstrate a new and highly efficient alternative mechanism by which the crowded protein environment on the surface of cellular membranes can directly contribute to membrane shape change.

Published

2012

14. Biomolecular transport and separation in nanotubular networks

Author

David B. Robinson, Jeanne C. Stachowiak, Haiqing Liu, Robert J. Meagher, Mark J. Stevens, Steven S. Branda, Carl C. Hayden, Anupama Sinha, Elisa Abate, Darryl Y. Sasaki, Julia Wang, Frank J. Zendejas, Amanda Carroll-Portillo, and George D. Bachand

Subjects

Membrane bending, Membrane, Materials science, Membrane curvature, Biophysics, Biological membrane, Nanotechnology, Adhesion, Membrane biophysics, Protein adsorption, Elasticity of cell membranes

Abstract

Cell membranes are dynamic substrates that achieve a diverse array of functions through multi-scale reconfigurations. We explore the morphological changes that occur upon protein interaction to model membrane systems that induce deformation of their planar structure to yield nanotube assemblies. In the two examples shown in this report we will describe the use of membrane adhesion and particle trajectory to form lipid nanotubes via mechanical stretching, and protein adsorption onto domains and the induction of membrane curvature through steric pressure. Through this work the relationship between membrane bending rigidity, protein affinity, and line tension of phase separated structures were examined and their relationship in biological membranes explored.

Published

2010

15. Directed Formation of Lipid Membrane Microdomains as High Affinity Sites for His-Tagged Proteins

Author

Darryl Y. Sasaki, Elisa A. Abate, Carl C. Hayden, Jane S. Hwang, and Michael S. Kent

Subjects

Iminodiacetic acid, Matrix (biology), Biochemistry, Maltose-Binding Proteins, Catalysis, chemistry.chemical_compound, Membrane Microdomains, Colloid and Surface Chemistry, Animals, Histidine, Lipid bilayer, POPC, Chemistry, Imino Acids, Proteins, Membranes, Artificial, Biological membrane, General Chemistry, Lipid Metabolism, Lipids, Membrane, Phosphatidylcholines, Biophysics, lipids (amino acids, peptides, and proteins), Carrier Proteins, Copper

Abstract

Lipid membranes composed of an iminodiacetic acid functionalized lipid, DSIDA, in a POPC matrix exhibited switchable properties via Cu(2+) recognition to rapidly assemble microdomains that act as high affinity sites for His-tagged proteins. The microdomains demonstrated an order of magnitude enhanced affinity for the proteins compared to homogeneously functionalized POPC membranes with Ni(2+)-NTA DOGS or Cu(2+)-DOIDA, while a rapid release and restoration of the original membrane was accomplished with micromolar concentrations of EDTA.

Published

2009

16. Steric Confinement of Proteins in Lipid Domains Can Drive Membrane Curvature and Tubulation

Author

Darryl Y. Sasaki, Carl C. Hayden, and Jeanne C. Stachowiak

Subjects

Membrane bending, Crystallography, Orientations of Proteins in Membranes database, Membrane, Membrane curvature, Chemistry, Vesicle, Biophysics, Biological membrane, Lipid bilayer, Elasticity of cell membranes

Abstract

Deformation of lipid membranes into curved structures such as buds and tubules is essential to many cellular processes. Lipid micro-domains are thought to co-localize with many curved membrane structures, inspiring ongoing exploration of a variety of roles for domains in membrane bending.We examined the role of lipid domains in spatial confinement of protein binding and discovered a new mechanism for curvature amplification that relies on global coupling. We formed giant unilamellar vesicles that contained insoluble lipid domains that strongly bound his-tagged proteins. We show that protein crowding on domain surfaces creates a protein layer that buckles outward, spontaneously bending the domain into stable, well-defined tubules as more proteins bind. In contrast to previously described bending mechanisms relying on local steric interactions between proteins and lipids (i.e. helix insertion into membranes), this mechanism produces tubules whose dimensions are defined by global parameters: binding energy and domain size. Our results suggest the intriguing possibility that domains can amplify membrane bending and define protrusion length scales by concentraing the steric interactions between the lipid bilayer and proteins. This mechanism may help explain the high curvatures induced by membrane bending proteins.View Large Image | View Hi-Res Image | Download PowerPoint Slide