Your search keyword '"H. Pace"' showing total 5 results

1. Protein-lipid interaction at low pH induces oligomerization of the MakA cytotoxin from Vibrio cholerae .

Author

Nadeem A, Berg A, Pace H, Alam A, Toh E, Ådén J, Zlatkov N, Myint SL, Persson K, Gröbner G, Sjöstedt A, Bally M, Barandun J, Uhlin BE, and Wai SN

Subjects

Cell Line, Cholera metabolism, Cryoelectron Microscopy, Humans, Hydrogen-Ion Concentration, Protein Structure, Secondary, Virulence Factors metabolism, Virus Internalization, Bacterial Proteins metabolism, Cytotoxins metabolism, Lipid Bilayers chemistry, Vibrio cholerae pathogenicity

Abstract

The α-pore-forming toxins (α-PFTs) from pathogenic bacteria damage host cell membranes by pore formation. We demonstrate a remarkable, hitherto unknown mechanism by an α-PFT protein from Vibrio cholerae . As part of the MakA/B/E tripartite toxin, MakA is involved in membrane pore formation similar to other α-PFTs. In contrast, MakA in isolation induces tube-like structures in acidic endosomal compartments of epithelial cells in vitro. The present study unravels the dynamics of tubular growth, which occurs in a pH-, lipid-, and concentration-dependent manner. Within acidified organelle lumens or when incubated with cells in acidic media, MakA forms oligomers and remodels membranes into high-curvature tubes leading to loss of membrane integrity. A 3.7 Å cryo-electron microscopy structure of MakA filaments reveals a unique protein-lipid superstructure. MakA forms a pinecone-like spiral with a central cavity and a thin annular lipid bilayer embedded between the MakA transmembrane helices in its active α-PFT conformation. Our study provides insights into a novel tubulation mechanism of an α-PFT protein and a new mode of action by a secreted bacterial toxin., Competing Interests: AN, KP, BU, SW S.N.W., B.E.U., A.N., and K.P. wish to make the disclosure that we are named inventors in a PCT application (Vibrio cholerae protein for use against cancer) published under No. WO 2021/071419. This does not alter our adherence to eLife policies on sharing data and materials, AB, HP, AA, ET, JÅ, NZ, SM, GG, AS, MB, JB No competing interests declared, (© 2022, Nadeem et al.)

Published

2022

2. Spatiotemporal Kinetics of Supported Lipid Bilayer Formation on Glass via Vesicle Adsorption and Rupture.

Author

Mapar M, Jõemetsa S, Pace H, Zhdanov VP, Agnarsson B, and Höök F

Subjects

Adsorption, Glass chemistry, Kinetics, Lipid Bilayers chemistry, Microscopy, Fluorescence, Molecular Dynamics Simulation, Monte Carlo Method, Particle Size, Surface Properties, Lipid Bilayers chemical synthesis

Abstract

Supported lipid bilayers (SLBs) represent one of the most popular mimics of the cell membrane. Herein, we have used total internal reflection fluorescence microscopy for in-depth characterization of the vesicle-mediated SLB formation mechanism on a common silica-rich substrate, borosilicate glass. Fluorescently labeling a subset of vesicles allowed us to monitor the adsorption of individual labeled vesicles, resolve the onset of SLB formation from small seeds of SLB patches, and track their growth via SLB-edge-induced autocatalytic rupture of adsorbed vesicles. This made it possible to perform the first quantitative measurement of the SLB front velocity, which is shown to increase up to 1 order of magnitude with time. This effect can be classified as dramatic because in many other physical, chemical, or biological kinetic processes the front velocity is either constant or decreasing with time. The observation was successfully described with a theoretical model and Monte Carlo simulations implying rapid local diffusion of lipids upon vesicle rupture.

Published

2018

3. Location-specific nanoplasmonic sensing of biomolecular binding to lipid membranes with negative curvature.

Author

Junesch J, Emilsson G, Xiong K, Kumar S, Sannomiya T, Pace H, Vörös J, Oh SH, Bally M, and Dahlin AB

Subjects

Silicon Dioxide chemistry, Biosensing Techniques methods, Lipid Bilayers chemistry, Nanostructures chemistry, Nanotechnology methods

Abstract

The biochemical processes of cell membranes are sensitive to the geometry of the lipid bilayer. We show how plasmonic "nanowells" provide label-free real-time analysis of molecules on membranes with detection of preferential binding at negative curvature. It is demonstrated that norovirus accumulate in invaginations due to multivalent interactions with glycosphingolipids.

Published

2015

4. Preserved transmembrane protein mobility in polymer-supported lipid bilayers derived from cell membranes.

Author

Pace H, Simonsson Nyström L, Gunnarsson A, Eck E, Monson C, Geschwindner S, Snijder A, and Höök F

Subjects

Amino Acid Sequence, Aspartic Acid Endopeptidases chemistry, Aspartic Acid Endopeptidases metabolism, Cell Line, Glass chemistry, Membrane Proteins chemistry, Models, Molecular, Molecular Conformation, Molecular Sequence Data, Surface Properties, Cell Membrane chemistry, Dimethylpolysiloxanes chemistry, Lipid Bilayers chemistry, Membrane Proteins metabolism, Movement, Phosphatidylcholines chemistry, Polyethylene Glycols chemistry

Abstract

Supported lipid bilayers (SLBs) have contributed invaluable information about the physiochemical properties of cell membranes, but their compositional simplicity often limits the level of knowledge that can be gained about the structure and function of transmembrane proteins in their native environment. Herein, we demonstrate a generic protocol for producing polymer-supported lipid bilayers on glass surfaces that contain essentially all naturally occurring cell-membrane components of a cell line while still retaining transmembrane protein mobility and activity. This was achieved by merging vesicles made from synthetic lipids (PEGylated lipids and POPC lipids) with native cell-membrane vesicles to generate hybrid vesicles which readily rupture into a continuous polymer-supported lipid bilayer. To investigate the properties of these complex hybrid SLBs and particularly the behavior of their integral membrane-proteins, we used total internal reflection fluorescence imaging to study a transmembrane protease, β-secretase 1 (BACE1), whose ectoplasmic and cytoplasmic domains could both be specifically targeted with fluorescent reporters. By selectively probing the two different orientations of BACE1 in the resulting hybrid SLBs, the role of the PEG-cushion on transmembrane protein lateral mobility was investigated. The results reveal the necessity of having the PEGylated lipids present during vesicle adsorption to prevent immobilization of transmembrane proteins with protruding domains. The proteolytic activity of BACE1 was unadulterated by the sonication process used to merge the synthetic and native membrane vesicles; importantly it was also conserved in the SLB. The presented strategy could thus serve both fundamental studies of membrane biophysics and the production of surface-based bioanalytical sensor platforms.

Published

2015

5. Protein separation by electrophoretic-electroosmotic focusing on supported lipid bilayers.

Author

Liu C, Monson CF, Yang T, Pace H, and Cremer PS

Subjects

Electricity, Fluorescent Dyes chemistry, Hydrogen-Ion Concentration, Osmolar Concentration, Temperature, Isoelectric Focusing, Lipid Bilayers chemistry, Membrane Proteins isolation & purification

Abstract

An electrophoretic-electroosmotic focusing (EEF) method was developed and used to separate membrane-bound proteins and charged lipids based on their charge-to-size ratio from an initially homogeneous mixture. EEF uses opposing electrophoretic and electroosmotic forces to focus and separate proteins and lipids into narrow bands on supported lipid bilayers (SLBs). Membrane-associated species were focused into specific positions within the SLB in a highly repeatable fashion. The steady-state focusing positions of the proteins could be predicted and controlled by tuning experimental conditions, such as buffer pH, ionic strength, electric field, and temperature. Careful tuning of the variables should enable one to separate mixtures of membrane proteins with only subtle differences. The EEF technique was found to be an effective way to separate protein mixtures with low initial concentrations, and it overcame diffusive peak broadening to allow four bands to be separated simultaneously within a 380 μm wide isolated supported membrane patch., (© 2011 American Chemical Society)

Published

2011