Proteo-lipobeads to encapsulate cytochrome c oxidase from Paracoccus denitrificans.

Proteo-lipobeads (PLBs) are investigated as cell-free model systems to encapsulate membrane proteins such as ion channels and transporters. PLBs are based on nickel nitrile tri-acetic acid (Ni-NTA)-functionalized agarose beads, onto which membrane proteins (MP) are bound via histidine(his)-tag. Composite beads thus obtained (subsequently called proteobeads) are dialyzed in the presence of lipid micelles to form PLBs.

pH and Potential Transients of the bc Complex Co-Reconstituted in Proteo-Lipobeads with the Reaction Center from Rb. sphaeroides.

His-tag technology is employed to bind membrane proteins, such as the bc complex and the reaction center (RC) from Rhodobacter sphaeroides, to spherical as well as planar surfaces in a strict orientation. Subsequently, the spherical and planar surfaces are subjected to in situ dialysis to form proteo-lipobeads (PLBs) and protein-tethered bilayer membranes, respectively. PLBs based on Ni-nitrileotriacetic acid-functionalized agarose beads that have diameters ranging from 50 to 150 μm are used to assess proton release and membrane potential parameters by confocal laser-scanning microscopy.

Kinetics of cytochrome c oxidase from R. sphaeroides initiated by direct electron transfer followed by tr-SEIRAS.

Time-resolved surface-enhanced IR-absorption spectroscopy (tr-SEIRAS) has been performed on cytochrome c oxidase from Rhodobacter sphaeroides. The enzyme was converted electrochemically into the fully reduced state. Thereafter, in the presence of oxygen, the potential was switched to open circuit potential (OCP).

Biomimetic Membranes for Multi-Redox Center Proteins.

His-tag technology was applied for biosensing purposes involving multi-redox center proteins (MRPs). An overview is presented on various surfaces ranging from flat to spherical and modified with linker molecules with nitrile-tri-acetic acid (NTA) terminal groups to bind his-tagged proteins in a strict orientation. The bound proteins are submitted to in situ dialysis in the presence of lipid micelles to form a so-called protein-tethered bilayer lipid membrane (ptBLM).

Proteo-lipobeads for the oriented encapsulation of membrane proteins.

As a surrogate of live cells, proteo-lipobeads are presented, encapsulating functional membrane proteins in a strict orientation into a lipid bilayer. Assays can be performed just as on live cells, for example using fluorescence measurements. As a proof of concept, we have demonstrated proton transport through cytochrome c oxidase.

Silica nanoparticles for the oriented encapsulation of membrane proteins into artificial bilayer lipid membranes.

An artificial bilayer lipid membrane system is presented, featuring the oriented encapsulation of membrane proteins in a functionally active form. Nickel nitrilo-triacetic acid-functionalized silica nanoparticles, of a diameter of around 25 nm, are used to attach the proteins via a genetically engineered histidine tag in a uniform orientation. Subsequently, the proteins are reconstituted within a phospholipid bilayer, formed around the particles by in situ dialysis to form so-called proteo-lipobeads (PLBs).

Phase-sensitive detection in modulation excitation spectroscopy applied to potential induced electron transfer in cytochrome c oxidase.

Cytochrome c oxidase (CcO) from Rhodobacter sphaeroides was investigated by modulated excitation surface-enhanced infrared-absorption spectroscopy (SEIRAS). Sequential electron transfer (ET) within CcO was initiated by electrochemical excitation. During modulated excitation by periodic potential pulses with frequencies between 20 and 500 Hz, time-resolved infrared spectra were measured by the step-scan technique, with time resolution in the millisecond range.

Time-resolved surface-enhanced IR-absorption spectroscopy of direct electron transfer to cytochrome c oxidase from R. sphaeroides.

Time-resolved surface-enhanced IR-absorption spectroscopy triggered by electrochemical modulation has been performed on cytochrome c oxidase from Rhodobacter sphaeroides. Single bands isolated from a broad band in the amide I region using phase-sensitive detection were attributed to different redox centers. Their absorbances changing on the millisecond timescale could be fitted to a model based on protonation-dependent chemical reaction kinetics established previously.

2D-SEIRA spectroscopy to highlight conformational changes of the cytochrome c oxidase induced by direct electron transfer.

Potentiometric titrations of the cytochrome c oxidase (CcO) immobilized in a biomimetic membrane system were followed by two-dimensional surface-enhanced IR absorption spectroscopy (2D SEIRAS) in the ATR-mode. Direct electron transfer was employed to vary the redox state of the enzyme. The CcO was shown to undergo a conformational transition from a non-activated to an activated state after it was allowed to turnover in the presence of oxygen.

Electron transfer kinetics of cytochrome c probed by time-resolved surface-enhanced resonance Raman spectroscopy.

An improved setup including a measuring cell was designed for time-resolved surface-enhanced resonance Raman (SERR) spectroscopy. The cell is based on a rotating disk electrode (RDE) made from electrochemically roughened Ag. Cytochrome c (cc) adsorbed on a monolayer of mercaptoethanol is investigated with respect to heterogeneous electron transfer.

Modeling ion transport in tethered bilayer lipid membranes. 1. Passive ion permeation.

Ion transport across tethered bilayer lipid membranes (tBLMs) is modeled using a hybrid network description which combines potential-dependent rate equations with passive electrical elements. Passive permeation of ions is described by the integrated Nernst-Planck equation. Simulations based on this model are performed with the network simulation program SPICE (simulation program with integrated circuit emphasis).

Protein tethered lipid bilayer: an alternative mimic of the biological membrane (Mini Review).

An overview is given about results obtained so far with an alternative concept of solid-supported tethered lipid bilayers for the functional incorporation of membrane proteins. The incorporated protein itself acts as the tethering molecule resulting in a versatile system where the protein determines the characteristics of submembraneous space. This architecture is achieved through a metal chelating surface, onto which histidine-tagged (his-tagged) membrane proteins are able to bind in a reversible manner.

In situ monitoring of the catalytic activity of cytochrome C oxidase in a biomimetic architecture.

Cytochrome c oxidase (CcO) from Paracoccus denitrificans was immobilized in a strict orientation via a his-tag attached to subunit I on a gold film and reconstituted in situ into a protein-tethered bilayer lipid membrane. In this orientation, the cytochrome c (cyt c) binding site is directed away from the electrode pointing to the outer side of the protein-tethered bilayer lipid membrane architecture. The CcO can thus be activated by cyt c under aerobic conditions.

Activity of membrane proteins immobilized on surfaces as a function of packing density.

A systematic study of the influence of the packing density of proteins on their activity is performed with cytochrome c oxidase (CcO) from R. sphaeroides as an example. The protein was incorporated into a protein-tethered bilayer lipid membrane and CcO was genetically engineered with a histidine-tag, attached to Subunit II, and then tethered by an interaction with functionalized thiol compounds bound to a gold electrode.

Electronic wiring of a multi-redox site membrane protein in a biomimetic surface architecture.

Bioelectronic coupling of multi-redox-site membrane proteins was accomplished with cytochrome c oxidase (CcO) as an example. A biomimetic membrane system was used for the oriented immobilization of the CcO oxidase on a metal electrode. When the protein is immobilized with the CcO binding side directed toward the electrode and reconstituted in situ into a lipid bilayer, it is addressable by direct electron transfer to the redox centers.