David Garenne scite author profile

The new generation of cell-free gene expression systems enables prototyping and engineering biological systems in vitro over a remarkable scope of applications and physical scales. As the utilization of DNA-directed in vitro protein synthesis expands in scope, developing more powerful cell-free transcription-translation (TXTL) platforms remains a major goal to either execute larger DNA programs, or improve cell-free biomanufacturing capabilities. In this work, we report the capabilities of the all E. coli TXTL toolbox 3.0, a multipurpose cell-free expression system specifically developed for synthetic biology. In non-fed batch mode reactions, synthesis of the fluorescent reporter protein eGFP reaches 4 mg/ml. In synthetic cells, consisting of liposomes loaded with a TXTL reaction, eGFP is produced to concentrations of more than 8 mg/ml when the chemical building blocks feeding the reaction diffuse through membrane channels to facilitate exchanges with the outer solution. The bacteriophage T7, encoded by a genome of 40 kbp and about 60 genes, is produced at a concentration of 1013 PFU/ml. This TXTL system extends the current cell-free expression capabilities by offering unique strength and properties, for either testing regulatory elements and circuits, biomanufacturing biologics, or building synthetic cells.

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Multiplex transcriptional characterizations across diverse bacterial species using cell‐free systems

Yim

Johns

Park

et al. 2019

Molecular Systems Biology

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Cell‐free expression systems enable rapid prototyping of genetic programs in vitro . However, current throughput of cell‐free measurements is limited by the use of channel‐limited fluorescent readouts. Here, we describe DNA Regulatory element Analysis by cell‐Free Transcription and Sequencing ( DRAFTS ), a rapid and robust in vitro approach for multiplexed measurement of transcriptional activities from thousands of regulatory sequences in a single reaction. We employ this method in active cell lysates developed from ten diverse bacterial species. Interspecies analysis of transcriptional profiles from > 1,000 diverse regulatory sequences reveals functional differences in promoter activity that can be quantitatively modeled, providing a rich resource for tuning gene expression in diverse bacterial species. Finally, we examine the transcriptional capacities of dual‐species hybrid lysates that can simultaneously harness gene expression properties of multiple organisms. We expect that this cell‐free multiplex transcriptional measurement approach will improve genetic part prototyping in new bacterial chassis for synthetic biology.

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Sequestration of Proteins by Fatty Acid Coacervates for Their Encapsulation within Vesicles

et al. 2016

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Encapsulating biological materials in lipid vesicles is of interest for mimicking cells; however, except in some particular cases, such processes do not occur spontaneously. Herein, we developed a simple and robust method for encapsulating proteins in fatty acid vesicles in high yields. Fatty acid based, membrane-free coacervates spontaneously sequester proteins and can reversibly form membranous vesicles upon varying the pH value, the precrowding feature in coacervates allowing for protein encapsulation within vesicles. We then produced enzyme-enriched vesicles and show that enzymatic reactions can occur in these micrometric capsules. This work could be of interest in the field of synthetic biology for building microreactors.

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Membrane molecular crowding enhances MreB polymerization to shape synthetic cells from spheres to rods

Garenne

Libchaber

Noireaux

2020

Proc. Natl. Acad. Sci. U.S.A.

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Executing gene circuits by cell-free transcription−translation into cell-sized compartments, such as liposomes, is one of the major bottom-up approaches to building minimal cells. The dynamic synthesis and proper self-assembly of macromolecular structures inside liposomes, the cytoskeleton in particular, stands as a central limitation to the development of cell analogs genetically programmed. In this work, we express the Escherichia coli gene mreB inside vesicles with bilayers made of lipid-polyethylene glycol (PEG). We demonstrate that two-dimensional molecular crowding, emulated by the PEG molecules at the lipid bilayer, is enough to promote the polymerization of the protein MreB at the inner membrane into a sturdy cytoskeleton capable of transforming spherical liposomes into elongated shapes, such as rod-like compartments. We quantitatively describe this mechanism with respect to the size of liposomes, lipid composition of the membrane, crowding at the membrane, and strength of MreB synthesis. So far unexplored, molecular crowding at the surface of synthetic cells emerges as an additional development with potential broad applications. The symmetry breaking observed could be an important step toward compartment self-reproduction.

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David Garenne

Cell-free gene expression

The all-E. coliTXTL toolbox 3.0: new capabilities of a cell-free synthetic biology platform

Multiplex transcriptional characterizations across diverse bacterial species using cell‐free systems

Sequestration of Proteins by Fatty Acid Coacervates for Their Encapsulation within Vesicles

Membrane molecular crowding enhances MreB polymerization to shape synthetic cells from spheres to rods

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