Thomas Heitkamp scite author profile

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.

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K⁺-Translocating KdpFABC P-Type ATPase from Escherichia coli Acts as a Functional and Structural Dimer

Heitkamp

Kalinowski

Böttcher

et al. 2008

Biochemistry

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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.

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Light‐Driven ATP Regeneration in Diblock/Grafted Hybrid Vesicles

et al. 2020

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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.

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Observing conformations of single F_oF₁-ATP synthases in a fast anti-Brownian electrokinetic trap

Düser

Zarrabi

et al. 2015

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To monitor conformational changes of individual membrane transporters in liposomes in real time, we attach two fluorophores to selected domains of a protein. Sequential distance changes between the dyes are recorded and analyzed by Förster resonance energy transfer (FRET). Using freely diffusing membrane proteins reconstituted in liposomes, observation times are limited by Brownian motion through the confocal detection volume. A. E. Cohen and W. E. Moerner have invented and built microfluidic devices to actively counteract Brownian motion of single nanoparticles in electrokinetic traps (ABELtrap). Here we present a version of an ABELtrap with a laser focus pattern generated by electrooptical beam deflectors and controlled by a programmable FPGA. This ABELtrap could hold single fluorescent nanobeads for more than 100 seconds, increasing the observation times of a single particle by more than a factor of 1000. Conformational changes of single FRET-labeled membrane enzymes FoF1-ATP synthase can be detected in the ABELtrap.

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Thomas Heitkamp

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

K⁺-Translocating KdpFABC P-Type ATPase from Escherichia coli Acts as a Functional and Structural Dimer

Light‐Driven ATP Regeneration in Diblock/Grafted Hybrid Vesicles

Observing conformations of single F_oF₁-ATP synthases in a fast anti-Brownian electrokinetic trap

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About

Thomas Heitkamp

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

K+-Translocating KdpFABC P-Type ATPase from Escherichia coli Acts as a Functional and Structural Dimer

Light‐Driven ATP Regeneration in Diblock/Grafted Hybrid Vesicles

Observing conformations of single FoF1-ATP synthases in a fast anti-Brownian electrokinetic trap

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Product

Resources

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K⁺-Translocating KdpFABC P-Type ATPase from Escherichia coli Acts as a Functional and Structural Dimer

Observing conformations of single F_oF₁-ATP synthases in a fast anti-Brownian electrokinetic trap