Cell-Free Systems: Functional Modules for Synthetic and Chemical Biology

Stech, Marlitt; Brödel, Andreas K.; Quast, Robert B.; Sachse, Rita; Kubick, Stefan

doi:10.1007/10_2013_185

Cited by 25 publications

(30 citation statements)

References 100 publications

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“…The determination of the optimal concentration of the previously described E. coli-derived mutant synthetase eAzFRS (Chin et al, 2003;Takimoto et al, 2009) in combination with a natural amber suppressor tRNA CUA from E. coli (Edwards and Schimmel, 1990) used in this study, was performed stochastically in batch-formatted reactions (data not shown). Based on earlier findings which indicated a significant influence of the cation concentration on the yield of cell-free synthesized proteins with incorporated AzF (Stech et al, 2013), we applied the automated workflow to an amber suppression screening varying the Mg 2+ concentration. Moreover, we also implemented a second dimension screening procedure using an iterative development process at different insect cell lysate concentrations.…”

Section: Application Of the Automated Synthesis For Amber Suppressionmentioning

confidence: 99%

“…On the one hand, fluorescent amino acid derivatives such as BODIPY-TMR-lysine can be directly incorporated into proteins in a statistical manner by sense codon reassignment using pre-charged tRNAs which allows for a sensitive detection of synthesized proteins . On the other hand, the site-directed incorporation of p-Azido-l-phenylalanine (AzF) based on amber suppression, mediated by an orthogonal tRNA/synthetase pair derived from E. coli, enabled us to fluorescently modify cell-free synthesized human erythropoietin in a selective manner by Staudinger ligation (Stech et al, 2013;Quast et al, 2014). The employment of amino acids with selective reactivity facilitates a subsequent modification of proteins to introduce a variety of different characteristics.…”

Section: Introductionmentioning

confidence: 99%

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Automated production of functional membrane proteins using eukaryotic cell-free translation systems

Quast

Kortt

Henkel

et al. 2015

Journal of Biotechnology

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Due to their high abundance and pharmacological relevance there is a growing demand for the efficient production of functional membrane proteins. In this context, cell-free protein synthesis represents a valuable alternative that allows for the high-throughput synthesis of functional membrane proteins. Here, we demonstrate the potential of our cell-free protein synthesis system, based on lysates from cultured Spodoptera frugiperda 21 cells, to produce pro- and eukaryotic membrane proteins with individual topological characteristics in an automated fashion. Analytical techniques, including confocal laser scanning microscopy, fluorescence detection of eYFP fusion proteins in a microplate reader and in-gel fluorescence of statistically incorporated fluorescent amino acid derivatives were employed. The reproducibility of our automated synthesis approach is underlined by coefficients of variation below 7.2%. Moreover, the functionality of the cell-free synthesized potassium channel KcsA was analyzed electrophysiologically. Finally, we expanded our cell-free membrane protein synthesis system by an orthogonal tRNA/synthetase pair for the site-directed incorporation of p-Azido-l-phenylalanine based on stop codon suppression. Incorporation was optimized by performance of a two-dimensional screening with different Mg(2+) and lysate concentrations. Subsequently, the selective modification of membrane proteins with incorporated p-Azido-l-phenylalanine was exemplified by Staudinger ligation with a phosphine-based fluorescence dye.

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Section: Application Of the Automated Synthesis For Amber Suppressionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Automated production of functional membrane proteins using eukaryotic cell-free translation systems

Quast

Kortt

Henkel

et al. 2015

Journal of Biotechnology

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“…Thus, protein synthesis is disconnected from cell fate and the protein synthesis reaction itself is not constrained by a cell wall, meaning that reaction conditions are accessible from the outside of the reaction vessel [5,7,42].…”

Section: Cell-free Protein Synthesismentioning

confidence: 99%

“…These features are made possible as the cell extract contains translationally active, endogenous microsomal vesicles having their origin in the ER of the insect cells. These vesicles are formed during the lysate preparation procedure, where the native structure of the ER is ripped, followed by its rearrangement and formation of smaller compartments designated as microsomal vesicles [5]. Due to the presence of these vesicles, target proteins can be translocated into the lumen of these vesicles, if they are fused to an appropriate signal sequence [65].…”

Section: Figurementioning

confidence: 99%

“…However, a cell-based production of target proteins is known to be rather time-consuming and cost-intensive, thus resulting in the development of efficient and powerful cell-free protein synthesis systems. Over the last decade, cellfree systems have proven themselves as reliable, flexible and potent protein production platform, providing proteins of varying origins, classes and properties [3][4][5][6][7]. In particular, cell-free systems have been successfully used for the synthesis of antibodies and antibody fragments [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

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Cell-Free Synthesis Meets Antibody Production: A Review

Stech

Kubick

2015

Antibodies

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Engineered antibodies are key players in therapy, diagnostics and research. In addition to full size immunoglobulin gamma (IgG) molecules, smaller formats of recombinant antibodies, such as single-chain variable fragments (scFv) and antigen binding fragments (Fab), have emerged as promising alternatives since they possess different advantageous properties. Cell-based production technologies of antibodies and antibody fragments are well-established, allowing researchers to design and manufacture highly specific molecular recognition tools. However, as these technologies are accompanied by the drawbacks of being rather time-consuming and cost-intensive, efficient and powerful cell-free protein synthesis systems have been developed over the last decade as alternatives. So far, prokaryotic cell-free systems have been the focus of interest. Recently, eukaryotic in vitro translation systems have enriched the antibody production pipeline, as these systems are able to mimic the natural pathway of antibody synthesis in eukaryotic cells. This review aims to overview and summarize the advances made in the production of antibodies and antibody fragments in cell-free systems.

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Cell‐Free Protein Synthesis: An Emerging Technology for Understanding, Harnessing, and Expanding the Capabilities of Biological Systems

Schoborg

Jewett

2018

Synthetic Biology

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Cell-Free Systems: Functional Modules for Synthetic and Chemical Biology

Cited by 25 publications

References 100 publications

Automated production of functional membrane proteins using eukaryotic cell-free translation systems

Automated production of functional membrane proteins using eukaryotic cell-free translation systems

Cell-Free Synthesis Meets Antibody Production: A Review

Cell‐Free Protein Synthesis: An Emerging Technology for Understanding, Harnessing, and Expanding the Capabilities of Biological Systems

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