Mechanism of ADP-Inhibited ATP Hydrolysis in Single Proton-Pumping FoF1-ATP Synthase Trapped in Solution.

FoF1-ATP synthases in mitochondria, in chloroplasts, and in most bacteria are proton-driven membrane enzymes that supply the cells with ATP made from ADP and phosphate. Different control mechanisms exist to monitor and prevent the enzymes' reverse chemical reaction of fast wasteful ATP hydrolysis, including mechanical or redox-based blockade of catalysis and ADP inhibition. In general, product inhibition is expected to slow down the mean catalytic turnover. Biochemical assays are ensemble measurements and cannot discriminate between a mechanism affecting all enzymes equally or individually. For example, all enzymes could work more slowly at a decreasing substrate/product ratio, or an increasing number of individual enzymes could be completely blocked. Here, we examined the effect of increasing amounts of ADP on ATP hydrolysis of single Escherichia coli FoF1-ATP synthases in liposomes. We observed the individual catalytic turnover of the enzymes one after another by monitoring the internal subunit rotation using single-molecule Förster resonance energy transfer (smFRET). Observation times of single FRET-labeled FoF1-ATP synthases in solution were extended up to several seconds using a confocal anti-Brownian electrokinetic trap (ABEL trap). By counting active versus inhibited enzymes, we revealed that ADP inhibition did not decrease the catalytic turnover of all FoF1-ATP synthases equally. Instead, increasing ADP in the ADP/ATP mixture reduced the number of remaining active enzymes that operated at similar catalytic rates for varying substrate/product ratios.

Fast ATP-Dependent Subunit Rotation in Reconstituted FoF1-ATP Synthase Trapped in Solution.

FoF1-ATP synthases are ubiquitous membrane-bound, rotary motor enzymes that can catalyze ATP synthesis and hydrolysis. Their enzyme kinetics are controlled by internal subunit rotation, by substrate and product concentrations, and by mechanical inhibitory mechanisms but also by the electrochemical potential of protons across the membrane. Single-molecule Förster resonance energy transfer (smFRET) has been used to detect subunit rotation within FoF1-ATP synthases embedded in freely diffusing liposomes. We now report that kinetic monitoring of functional rotation can be prolonged from milliseconds to seconds by utilizing an anti-Brownian electrokinetic trap (ABEL trap). These extended observation times allowed us to observe fluctuating rates of functional rotation for individual FoF1-liposomes in solution. Broad distributions of ATP-dependent catalytic rates were revealed. The buildup of an electrochemical potential of protons was confirmed to limit the maximum rate of ATP hydrolysis. In the presence of ionophores or uncouplers, the fastest subunit rotation speeds measured in single reconstituted FoF1-ATP synthases were 180 full rounds per second. This was much faster than measured by biochemical ensemble averaging, but not as fast as the maximum rotational speed reported previously for isolated single F1 complexes uncoupled from the membrane-embedded Fo complex. Further application of ABEL trap measurements should help resolve the mechanistic causes of such fluctuating rates of subunit rotation.

Light-Driven ATP Regeneration in Diblock/Grafted Hybrid Vesicles.

Light-driven ATP regeneration systems combining ATP synthase and bacteriorhodopsin have been proposed as an energy supply in the field of synthetic biology. Energy is required to power biochemical reactions within artificially created reaction compartments like protocells, which are typically based on either lipid or polymer membranes. The insertion of membrane proteins into different hybrid membranes is delicate, and studies comparing these systems with liposomes are needed. Here we present a detailed study of membrane protein functionality in different hybrid compartments made of graft polymer PDMS-g-PEO and diblock copolymer PBd-PEO. Activity of more than 90 % in lipid/polymer-based hybrid vesicles could prove an excellent biocompatibility. A significant enhancement of long-term stability (80 % remaining activity after 42 days) could be demonstrated in polymer/polymer-based hybrids.

Towards monitoring conformational changes of the GPCR neurotensin receptor 1 by single-molecule FRET.

Neurotensin receptor 1 (NTSR1) is a G protein-coupled receptor that is important for signaling in the brain and the gut. Its agonist ligand neurotensin (NTS), a 13-amino-acid peptide, binds with nanomolar affinity from the extracellular side to NTSR1 and induces conformational changes that trigger intracellular signaling processes. Our goal is to monitor the conformational dynamics of single fluorescently labeled NTSR1. For this, we fused the fluorescent protein mNeonGreen to the C terminus of NTSR1, purified the receptor fusion protein from E. coli membranes, and reconstituted NTSR1 into liposomes with E. coli polar lipids. Using single-molecule anisotropy measurements, NTSR1 was found to be monomeric in liposomes, with a small fraction being dimeric and oligomeric, showing homoFRET. Similar results were obtained for NTSR1 in detergent solution. Furthermore, we demonstrated agonist binding to NTSR1 by time-resolved single-molecule Förster resonance energy transfer (smFRET), using neurotensin labeled with the fluorophore ATTO594.

Sequential bottom-up assembly of mechanically stabilized synthetic cells by microfluidics.

Compartments for the spatially and temporally controlled assembly of biological processes are essential towards cellular life. Synthetic mimics of cellular compartments based on lipid-based protocells lack the mechanical and chemical stability to allow their manipulation into a complex and fully functional synthetic cell. Here, we present a high-throughput microfluidic method to generate stable, defined sized liposomes termed 'droplet-stabilized giant unilamellar vesicles (dsGUVs)'. The enhanced stability of dsGUVs enables the sequential loading of these compartments with biomolecules, namely purified transmembrane and cytoskeleton proteins by microfluidic pico-injection technology. This constitutes an experimental demonstration of a successful bottom-up assembly of a compartment with contents that would not self-assemble to full functionality when simply mixed together. Following assembly, the stabilizing oil phase and droplet shells are removed to release functional self-supporting protocells to an aqueous phase, enabling them to interact with physiologically relevant matrices.

Regulatory conformational changes of the ε subunit in single FRET-labeled FoF1-ATP synthase.

Subunit ε is an intrinsic regulator of the bacterial FoF1-ATP synthase, the ubiquitous membrane-embedded enzyme that utilizes a proton motive force in most organisms to synthesize adenosine triphosphate (ATP). The C-terminal domain of ε can extend into the central cavity formed by the α and ß subunits, as revealed by the recent X-ray structure of the F1 portion of the Escherichia coli enzyme. This insertion blocks the rotation of the central γ subunit and, thereby, prevents wasteful ATP hydrolysis. Here we aim to develop an experimental system that can reveal conditions under which ε inhibits the holoenzyme FoF1-ATP synthase in vitro. Labeling the C-terminal domain of ε and the γ subunit specifically with two different fluorophores for single-molecule Förster resonance energy transfer (smFRET) allowed monitoring of the conformation of ε in the reconstituted enzyme in real time. New mutants were made for future three-color smFRET experiments to unravel the details of regulatory conformational changes in ε.

Generation of an antibody toolbox to characterize hERG.

The human ether-a-go-go related gene (hERG) potassium channel plays a major role in the repolarization of the cardiac action potential. Inhibition of the hERG function by mutations or a wide variety of pharmaceutical compounds cause long QT syndrome and lead to potentially lethal arrhythmias. For detailed insights into the structural and biochemical background of hERG function and drug binding, the purification of recombinant protein is essential. Because the hERG channel is a challenging protein to purify, fast and easy techniques to evaluate different expression, solubilization and purification conditions are of primary importance. Here, we describe the generation of a set of 12 monoclonal antibodies against hERG. Beside their suitability in western blot, immunoprecipitation and immunostaining, these antibodies were used to establish a sandwich ELISA for the detection and relative quantification of hERG in different expression systems. Furthermore, a Fab fragment was used in fluorescence size exclusion chromatography to determine the oligomeric state of hERG after solubilization. These new tools can be used for a fast and efficient screening of expression, solubilization and purification conditions.

Solution structure of the KdpFABC P-type ATPase from Escherichia coli by electron microscopic single particle analysis.

The K+-translocating KdpFABC complex from Escherichia coli functions as a high affinity potassium uptake system and belongs to the superfamily of P-type ATPases, although it exhibits some unique features. It comprises four subunits, and the sites of ATP hydrolysis and substrate transport are located on two different polypeptides. No structural data are so far available for elucidating the correspondingly unique mechanism of coupling ion transport and catalysis in this P-type ATPase. By use of electron microscopy and single particle analysis of negatively stained, solubilized KdpFABC complexes, we solved the structure of the complex at a resolution of 19A, which allowed us to model the arrangement of subunits within the holoenzyme and, thus, to identify the interfaces between subunits. The model showed that the K+-translocating KdpA subunit is in close contact with the transmembrane region of the ATP-hydrolyzing subunit KdpB. The cytosolic C-terminal domain of the KdpC subunit, which is assumed to play a role in cooperative ATP binding together with KdpB, is located in close vicinity to the nucleotide binding domain of KdpB. Overall, the arrangement of subunits agrees with biochemical data and the predictions on subunit interactions.

K+-translocating KdpFABC P-type ATPase from Escherichia coli acts as a functional and structural dimer.

The membrane-embedded K (+)-translocating KdpFABC complex from Escherichia coli belongs to the superfamily of P-type ATPases, which share common structural features as well as a well-studied catalytic mechanism. However, little is known about the oligomeric state of this class of enzymes. For many P-type ATPases, such as the Na (+)/K (+)-ATPase, Ca (2+)-ATPase, or H (+)-ATPase, an oligomeric state has been shown or is at least discussed but has not yet been characterized in detail. In the KdpFABC complex, kinetic analyses already indicated the presence of two cooperative ATP-binding sides within the functional enzyme and, thus, also point in the direction of a functional oligomer. However, the nature of this oligomeric state has not yet been fully elucidated. In the present work, a close vicinity of two KdpB subunits within the functional KdpFABC complex could be demonstrated by chemical cross-linking of native cysteine residues using copper 1,10-phenanthroline. The cysteines responsible for cross-link formation were identified by mutagenesis. Cross-linked and non-cross-linked KdpFABC complexes eluted with the same apparent molecular weight during gel filtration, which corresponded to the molecular weight of a homodimer, thereby clearly indicating that the KdpFABC complex was purified as a dimer. Isolated KdpFABC complexes were analyzed by transmission electron microscopy and exhibited an approximately 1:1 distribution of mono- and dimeric particles. Finally, reconstituted functional KdpFABC complexes were site-directedly labeled with flourescent dyes, and intermolecular single-molecule FRET analysis was carried out, from which a dissociation constant for a monomer/dimer equilibrium between 30 and 50 nM could be derived.

The transmembrane domain of subunit b of the Escherichia coli F1F(O) ATP synthase is sufficient for H(+)-translocating activity together with subunits a and c.

Subunit b is indispensable for the formation of a functional H(+)-translocating F(O) complex both in vivo and in vitro. Whereas the very C-terminus of subunit b interacts with F(1) and plays a crucial role in enzyme assembly, the C-terminal region is also considered to be necessary for proper reconstitution of F(O) into liposomes. Here, we show that a synthetic peptide, residues 1-34 of subunit b (b(1-34)) [Dmitriev, O., Jones, P.C., Jiang, W. & Fillingame, R.H. (1999) J. Biol. Chem.274, 15598-15604], corresponding to the membrane domain of subunit b was sufficient in forming an active F(O) complex when coreconstituted with purified ac subcomplex. H(+) translocation was shown to be sensitive to the specific inhibitor N,N'-dicyclohexylcarbodiimide, and the resulting F(O) complexes were deficient in binding of isolated F(1). This demonstrates that only the membrane part of subunit b is sufficient, as well as necessary, for H(+) translocation across the membrane, whereas the binding of F(1) to F(O) is mainly triggered by C-terminal residues beyond Glu34 in subunit b. Comparison of the data with former reconstitution experiments additionally indicated that parts of the hydrophilic portion of the subunit b dimer are not involved in the process of ion translocation itself, but might organize subunits a and c in F(O) assembly. Furthermore, the data obtained functionally support the monomeric NMR structure of the synthetic b(1-34).