Your search keyword '"Brandon R Bruhn"' showing total 7 results

1. Single Molecule Characterization of Cholera Toxin and its Interaction with Gm1 Gangliosides Using Lipid-Coated Nanopores

Author

Anirudh Vinnakota, Erik Yusko, Michael Mayer, and Brandon R. Bruhn

Subjects

Chemistry, Bilayer, Cholera toxin, Biophysics, Ligand (biochemistry), medicine.disease_cause, Receptor–ligand kinetics, Nanopore, Biochemistry, Vibrio cholerae, medicine, Molecule, lipids (amino acids, peptides, and proteins), Lipid bilayer

Abstract

Characterization of resistive pulses from the translocation of particles through lipid-coated nanopores has previously been used to determine the size, charge, and ligand affinity of proteins. Here, we coat the nanopores with a lipid bilayer to prevent non-specific adsorption, concentrate a protein of interest on the bilayer surface, and slow the translocation times of proteins through the pore so that events may be effectively time-resolved and detected. This study aims to characterize cholera toxin and the binding kinetics of the multivalent interaction with GM1 gangliosides embedded in the lipid coating. Understanding the parameters of the GM1 and cholera toxin interaction on a single molecule basis may provide additional information about the pathophysiology of vibrio cholerae, which is known to attack GM1 dense cells in the intestinal epithelia. By monitoring the frequency of translocation events of the protein-ligand complex as a function of time, it is possible to measure the binding kinetics of the interaction between cholera toxin and the GM1 lipid anchors. Thus far, we have determined the shape, volume, and charge of the membrane-associated protein in addition to the effective on-rate of binding under varying concentrations of the GM1 ligand.

Published

2015

2. Characterizing Shape, Dipole Moment, and Rotation of Single Proteins in Nanopores

Author

Ryan Rollings, Mariya A. Pindrus, David Sept, Erik Yusko, Jiali Li, Michael Mayer, Devendra S. Kalonia, Olivia M. Eggenberger, Nathan Walsh, and Brandon R. Bruhn

Subjects

chemistry.chemical_classification, Quantitative Biology::Biomolecules, Physics::Biological Physics, Materials science, Biomolecule, Biophysics, Ionic bonding, Rotational diffusion, Characterization (materials science), Moment (mathematics), Quantitative Biology::Subcellular Processes, Nanopore, Dipole, chemistry, Chemical physics, Lipid bilayer

Abstract

Proteins represent the most diverse class of biomolecules in both structure and function and are involved in nearly every physiological process; their quantification, identification, and biophysical characterization is therefore of fundamental and practical importance. This work used electrolyte-filled nanopores that were coated with a lipid bilayer to characterize single, native proteins that were anchored to mobile ligands in the coating. This technique has previously been used to determine a protein's volume, charge, and ligand affinity by measuring the change in ionic current, ΔI, through the nanopore as proteins travel from one side to the other. Here, we took advantage of the dependence of ΔI on the orientation of a non-spherical particle in the nanopore to determine the shape and volume of eight different non-spherical proteins from the resulting distributions of ΔI values. Additionally, we present quantitative methods for determining the dipole moment and rotational diffusion coefficient of non-spherical proteins from single events and compare results from established techniques as well as simulations based on theory.

Published

2014

3. An Exploration into the Optimal Lipid Coating for Nanopore-Based Protein Characterization

Author

Brandon R. Bruhn, Olivia M. Eggenberger, Michael Mayer, Jerry Yang, Haiyan Liu, and Geoffray Leriche

Subjects

Nanopore, Materials science, Coating, Biophysics, engineering, Nanotechnology, engineering.material, Characterization (materials science)

Published

2017

4. A Systematic Investigation to Determine the Optimal Lipid Coating for Nanopore-Based Sensing Experiments

Author

Geoffray Leriche, Haiyan Liu, Brandon R. Bruhn, Jerry Yang, Olivia M. Eggenberger, and Michael Mayer

Subjects

Crystallography, Chemistry, Membrane lipids, Bilayer, Peripheral membrane protein, Biophysics, lipids (amino acids, peptides, and proteins), Biological membrane, Lipid bilayer phase behavior, Model lipid bilayer, Lipid bilayer, Elasticity of cell membranes

Abstract

Despite the importance of proteins, nanopore sensing has so far been mostly focused on single molecule DNA and RNA characterization. One factor that limited experiments with proteins were nonspecific interactions of proteins with the walls of synthetic nanopores. We showed recently, that nanopores with fluid coatings of phospholipid bilayers circumvented this problem. In addition, anchoring proteins to lipid anchors slowed down protein translocation through nanopores and enabled determination of parameters such as the shape, volume, and dipole moment of individual non-spherical proteins. To slow down the translocation time of lipid-anchored proteins further, we have recently formed highly viscous coatings from archaea-inspired lipids. These synthetic lipids are composed of two hydrophilic head groups connected by a long hydrophobic chain; each head group is also attached to an acyl chain that spans half of the membrane thickness. As these lipids contain -in one molecule- the components of a typical lipid bilayer, a single layer is sufficient to form a stable membrane. Experimentation with many lipid coatings, including a variety of archaea-inspired lipids, has revealed differences in translocation of protein, bilayer stability and event frequency. Every bilayer composition tested has been designed to optimize each of these characteristics.

Published

2015

5. Highly Viscous Coatings from Archaea-Inspired Lipids Improve Single Protein Characterization with Nanopores

Author

Geoffray Leriche, Olivia M. Eggenberger, Haiyan Liu, Michael Mayer, Jerry Yang, and Brandon R. Bruhn

Subjects

Quantitative Biology::Biomolecules, Physics::Biological Physics, Chemistry, Membrane lipids, Peripheral membrane protein, Biophysics, Phospholipid, Quantitative Biology::Subcellular Processes, Nanopore, chemistry.chemical_compound, Membrane, Biochemistry, Monolayer, lipids (amino acids, peptides, and proteins), Lipid bilayer, Elasticity of cell membranes

Abstract

Despite the importance of proteins, nanopore sensing has so far been mostly focused on single molecule DNA and RNA characterization. One factor that limited experiments with proteins were nonspecific interactions of proteins with the walls of synthetic nanopores. We showed recently, that nanopores with fluid coatings of phospholipid bilayers circumvented this problem. In addition, anchoring proteins to lipid anchors slowed down protein translocation through nanopores and enabled determination of parameters such as the shape, volume, and dipole moment of individual non-spherical proteins. To slow down the translocation time of lipid-anchored proteins further, we have recently formed highly viscous coatings from archaea-inspired lipids. These synthetic lipids are composed of two hydrophilic head groups connected by a long hydrophobic chain; each head group is also attached to an acyl chain that spans half of the membrane thickness. As these lipids contain -in one molecule- the components of a typical lipid bilayer, a single layer is sufficient to form a stable membrane. Monolayers of these new lipids have a two to twenty-fold increased viscosity than typical phospholipid bilayers. The Archaea-inspired lipids discussed here show promise in terms of slowing translocation times and the resulting data made it possible to characterize individual proteins with increased accuracy than coatings from standard phospholipid bilayers.

Published

2014

6. Dynamics of Bio-Inspired Pressure Generation

Author

Suyi Li, Kon-Well Wang, Michael Mayer, Brandon R. Bruhn, Yazan N. Billeh, and Thomas Schroeder

Subjects

Work (thermodynamics), Bulk modulus, Materials science, Computer simulation, Surface-area-to-volume ratio, Volume (thermodynamics), Dynamics (mechanics), Biophysics, Mechanics, Osmosis, Dilution

Abstract

The capability of plant cells to establish osmotic gradients allows them to actuate structures such as guard cells and the pulvini responsible for the swift nastic motion of mimosa pudica. The work presented here investigated the dynamics of osmotically-driven pressure generation in membrane-bound compartments, taking into account volume expansion, solute dilution, surface area to volume ratio, membrane hydraulic permeability, and changes in osmotic gradient and bulk modulus. We developed and experimentally validated a numerical simulation tool for characterizing and predicting the dynamics of pressure generators as a function of parameters that will be encountered in most systems that generate pressure osmotically. Finally, we demonstrate two applications of an osmosis-based pressure generator: actuation of a soft robot and continuous volume delivery over long periods of time.

Published

2014

7. Dual-Pore Glass Chips for Single-Channel Recording

Author

Michael Mayer and Brandon R. Bruhn

Subjects

Suction, Materials science, Planar, business.industry, Capacitive sensing, Biophysics, Pipette, Optoelectronics, Dielectric, business, Noise (electronics), Seal (mechanical), Communication channel

Abstract

Despite the widespread use of high-throughput planar patch-clamp instruments, the conventional pipette-based technique remains the method of choice for recording single-channel activity. Generally, planar platforms are not well suited for single-channel studies due to excess noise resulting from low seal resistances and the use of substrates with poor dielectric properties. Since these platforms typically use the same pore to position a cell by suction and establish a seal, biological debris from the cell suspension can contaminate the pore surface prior to seal formation, thereby reducing the seal resistance. Here, femtosecond laser ablation is used to fabricate dual-pore glass chips for use in low-noise, single-channel recordings that circumvent this problem. One pore positions a cell by suction while another nearby pore, the recording pore, avoids contamination by maintaining positive pressure until a cell is positioned and then establishes a seal. Taking advantage of the high seal resistances and low capacitive and dielectric noise realized using glass substrates, patch-clamp experiments with these dual-pore chips consistently achieved high seal resistances (>10 GΩ), maintained gigaseals for prolonged durations (up to 6 hrs), and enabled single-channel recordings in cell-attached mode that are comparable to those obtained by conventional patch-clamp.View Large Image | View Hi-Res Image | Download PowerPoint Slide

Published

2013