Poly(dimethylsiloxane)-Coated Sensor Devices for the Formation of Supported Lipid Bilayers and the Subsequent Study of Membrane Interactions (original) (raw)
Related papers
Biomimetic lipid bilayers on solid surfaces: models for biological interactions
Biomimetic lipid bilayer platforms on solid supports, or solid-supported lipid bilayers (SLBs), are important model membrane systems for studying the fundamental properties of biological membranes and their constituent lipid and protein molecules. SLBs with different properties and functionalities can be designed by changing their lipid content (charged, uncharged, saturated, etc.), adding various membrane components (glycolipids, cholesterol, etc.) or incorporating membrane proteins (receptors, ion channels, etc.). They allow the usage of surface-sensitive characterization techniques such as atomic force spectroscopy, surface plasmon resonance (SPR) and the use of acoustic sensors such as quartz crystal microbalance with dissipation monitoring (QCM-D). Both QCM-D and SPR can supply information about binding events on surfaces and the properties of the resulting lipid films in real time by using frequency-dissipation changes and refractive index shift, respectively. In recent years, the potential of SLBs in numerous practical applications, such as the construction of drug screening or cancer cell detection platforms, has been explored. These platforms address some of the important challenges faced in cell membrane and membrane protein research and make membrane-related applications possible. Notation C mass sensitivity constant D ratio of the energy lost (dissipated) during one oscillation cycle to the total energy stored in the oscillator E lost energy lost (dissipated) during one oscillation cycle E stored total energy stored in the oscillator DD dissipation change in QCM-D Df frequency change of QCM-D Dm adsorbed mass in QCM-D
Spectroscopy, 2002
Planar lipid bilayers on sensor chip surfaces have become useful tools to study membrane bound processes by surface plasmon resonance spectroscopy. We immobilized phospholipids on sensor chips by different approaches. First, a self-assembled monolayer of octadecylmercaptan was formed on a blank gold surface and subsequent addition of phospholipids led to formation of a heterobilayer. Second, a self-assembled monolayer of mercaptoundecanoic acid was formed on a gold surface, the carboxy groups of mercaptoundecanoic acid were activated and covalently linked to phosphatidylethanolamine. Addition of phospholipids then led to a bilayer with phosphatidylethanolamine as the lower leaflet. Third, a hydrophobic sensor chip (L1, BIAcore) was used as a binding matrix for phospholipids. These lipid surfaces were tested, whether they are suitable to study proteinamembrane interactions. As biological test system we used the Ca2+-myristoyl-switch of the neuronal Ca2+-binding protein recoverin. All...
Surface plasmon resonance analysis at a supported lipid monolayer
Biochimica et Biophysica Acta (BBA) - Biomembranes, 1998
Methods for the formation of supported lipid monolayers on top of a hydrophobic self assembled monolayer in a surface plasmon resonance instrument are described. Small unilamellar vesicles absorb spontaneously to the surface of the hydrophobic self-assembled monolayer to form a surface which resembles the surface of a cellular membrane. Lipophilic ligands, such as small acylated peptides or glycosylphosphatidylinositol-anchored proteins, were inserted into the absorbed lipid and binding of analytes to these ligands was analysed by surface plasmon resonance. Conditions for the formation of lipid monolayers have been optimised with respect to lipid type, chemical and buffer compatibility, ligand stability and reproducibility. ß
2010
Surface plasmon resonance has become one of the most important techniques for studying bimolecular interactions. Most of the researchers are using it to study protein-protein interactions, but in recent years membrane model systems have also become available and this makes it possible to study proteinmembrane interactions as well. In this review chapter we describe possible ways to prepare lipid membrane surfaces on various sensor chips and some of the experimental considerations one has to take into account when performing such experiments.
Langmuir, 2021
The interactions of mono-rhamnolipids (mono-RLs) with model membranes were investigated through a biomimetic approach using phospholipid-based liposomes immobilized on a gold substrate and also by the multi-parametric surface plasmon resonance (MP-SPR) technique. Biotinylated liposomes were bound onto a SPR gold chip surface coated with a streptavidin layer. The resulting MP-SPR signal proved the efficient binding of the liposomes. The thickness of the liposome layer calculated by modeling the MP-SPR signal was about 80 nm, which matched the average diameter of the liposomes. The mono-RL binding to the film of the phospholipid liposomes was monitored by SPR and the morphological changes of the liposome layer were assessed by modeling the SPR signal. We demonstrated the capacity of the MP-SPR technique to characterize the different steps of the liposome architecture evolution, i.e. from a monolayer of phospholipid liposomes to a single phospholipid bilayer induced by the interaction with mono-RLs. Further washing treatment with Triton X-100 detergent left a monolayer of phospholipid on the surface. As a possible practical application, our method based on a biomimetic membrane coupled to a SPR measurement proved to be a robust and sensitive analytical tool for the detection of mono-RLs with a limit of detection of 2 µg mL −1 .
Analytical Chemistry, 2009
Short peptides, composed of polar or ionic amino acids, derived with a short organic thiol, significantly reduce nonspecific adsorption of proteins in complex biological matrices such as serum and crude cell lysate, which have nonspecific protein concentrations of 76 and 30-60 mg/ mL, respectively. Minimizing these nonspecific interactions has allowed rapid and direct quantification of -lactamase in a crude cell lysate using a surface plasmon resonance (SPR) biosensor. A library of short peptides with varying chain length and amino acid composition were synthesized using a solid-phase approach. A 3-mercaptopropionic acid (3-MPA) linker was covalently attached to the amino terminus of the peptides to subsequently form a monolayer on gold in the form of 3-MPA-(AA) n -OH, where n is the length of the amino acid chain (n ) 2-5). Leu, Phe, Ser, Asp, and His were selected to investigate the effect on nonspecific adsorption with different physicochemical properties of the sidechains; aliphatic, aromatic, polar, acid, and base. Advancing contact angles measured the hydrophobicity of each peptidic self-assembled monolayer (SAM) and showed that hydrophilicity of the gold surface improved as the chain length of the polar or ionic peptides increased, while aromatic and aliphatic peptides decreased the hydrophilicity as the chain length increased. The nonspecific adsorption of undiluted bovine serum on SPR sensors prepared with the library of 3-MPA-(AA) n -OH showed that the lowest nonspecific adsorption occurred with polar or ionic amino acids with a chain length of n ) 5. We demonstrate that a monolayer composed of 3-MPA-(Ser) 5 -OH has significant advantages, including the following: (1) it minimizes nonspecific adsorption in undiluted bovine serum; (2) it provides a high surface concentration of immobilized antibodies; (3) it shows a great retention of activity for the antibodies; (4) it improves the response from -lactamase by ∼1 order of magnitude, compared to previous experiments; and (5) it allows direct quantification of submicromolar -lactamase concentration in a crude cell lysate with a nonspecific protein concentration of 30-60 mg/mL. The use of this peptide-based monolayer offers great advantages for quantitative SPR biosensing in complex biological media.
Solid supported lipid membranes: New concepts for the biomimetic functionalization of solid surfaces
Biointerphases, 2008
Surface-layer (S-layer) supported lipid membranes on solid substrates are interfacial architectures mimicking the supramolecular principle of cell envelopes which have been optimized for billions of years of evolution in most extreme habitats. The authors implement this biological construction principle in a variety of layered supramolecular architectures consisting of a stabilizing protein monolayer and a functional phospholipid bilayer for the design and development of new types of solid-supported biomimetic membranes with a considerably extended stability and lifetimecompared to existing platforms-as required for novel types of bioanalytical sensors. First, Langmuir monolayers of lipids at the water/air interface are used as test beds for the characterization of different types of molecules which all interact with the lipid layers in various ways and, hence, are relevant for the control of the structure, stability, and function of supported membranes. As an example, the interaction of S-layer proteins from the bulk phase with a monolayer of a phospholipid synthetically conjugated with a secondary cell wall polymer (SCWP) was studied as a function of the packing density of the lipids in the monolayer. Furthermore, SCWPs were used as a new molecular construction element. The exploitation of a specific lectintype bond between the N-terminal part of selected S-layer proteins and a variety of glycans allowed for the buildup of supramolecular assemblies and thus functional membranes with a further increased stability. Next, S-layer proteins were self-assembled and characterized by the surface-sensitive techniques, surface plasmon resonance spectroscopy and quartz crystal microbalance with dissipation monitoring. The substrates were either planar gold or silicon dioxide sensor surfaces. The assembly of S-layer proteins from solution to solid substrates could nicely be followed in-situ and in real time. As a next step toward S-layer supported bilayer membranes, the authors characterized various architectures based on lipid molecules that were modified by a flexible spacer separating the amphiphiles from the anchor group that allows for a covalent coupling of the lipid to a solid support, e.g., using thiols for Au substrates. Impedance spectroscopy confirmed the excellent charge barrier properties of these constructs with a high electrical resistance. Structural details of various types of these tethered bimolecular lipid membranes were studied by using neutron reflectometry. Finally, first attempts are reported to develop a code based on a SPICE network analysis program which is suitable for the quantitative
Langmuir, 2014
There is an increasing interest to express and study membrane proteins in vitro. New techniques to produce and insert functional membrane proteins into planar lipid bilayers have to be developed. In this work, we produce a tethered lipid bilayer membrane (tBLM) to provide sufficient space for the incorporation of the integral membrane protein (IMP) Aquaporin Z (AqpZ) between the tBLM and the surface of the sensor. We use a gold (Au)-coated sensor surface compatible with mechanical sensing using a quartz crystal microbalance with dissipation monitoring (QCM-D) or optical sensing using the surface plasmon resonance (SPR) method. tBLM is produced by vesicle fusion onto a thin gold film, using phospholipid-polyethylene glycol (PEG) as a spacer. Lipid vesicles are composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) and 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-Npoly(ethyleneglycol)-2000-N-[3-(2-pyridyldithio)propionate], so-called DSPE-PEG-PDP, at different molar ratios (respectively, 99.5/0.5, 97.5/2.5, and 95/5 mol %), and tBLM formation is characterized using QCM-D, SPR, and atomic force technology (AFM). We demonstrate that tBLM can be produced on the gold surface after rupture of the vesicles using an α helical (AH) peptide, derived from hepatitis C virus NS5A protein, to assist the fusion process. A cell-free expression system producing the E. coli integral membrane protein Aquaporin Z (AqpZ) is directly incubated onto the tBLMs for expression and insertion of the IMP at the upper side of tBLMs. The incorporation of AqpZ into bilayers is monitored by QCM-D and compared to a control experiment (without plasmid in the cellfree expression system). We demonstrate that an IMP such as AqpZ, produced by a cell-free expression system without any protein purification, can be incorporated into an engineered tBLM preassembled at the surface of a gold-coated sensor.