Preparative scale expression of membrane proteins in Escherichia coli-based continuous exchange cell-free systems

Cell-free expression is emerging as a prime method for the rapid production of preparative quantities of high-quality membrane protein samples. The technology facilitates easy access to large numbers of proteins that have been extremely difficult to obtain. Most frequently used are cell-free systems based on extracts of Escherichia coli cells, and the reaction procedures are reliable and efficient. This protocol describes the preparation of all essential reaction components such as the E. coli cell extract, T7 RNA polymerase, DNA templates as well as the individual stock solutions. The setups of expression reactions in analytical and preparative scales, including a variety of reaction designs, are illustrated. We provide detailed reaction schemes that allow the preparation of milligram amounts of functionally folded membrane proteins of prokaryotic and eukaryotic origin in less than 24 h.     

Insertion of membrane proteins into discoidal membranes using a cell-free protein expression approach

We report a cell-free approach for expressing and inserting integral membrane proteins into water-soluble particles composed of discoidal apolipoprotein-lipid bilayers. Proteins are inserted into the particles, circumventing the need of extracting and reconstituting the product into membrane vesicles. Moreover, the planar nature of the membrane support makes the protein freely accessible from both sides of the lipid bilayer. Complexes are successfully purified by means of the apoplipoprotein component or by the carrier protein. The method significantly enhances the solubility of a variety of membrane proteins with different functional roles and topologies. Analytical assays for a subset of model membrane proteins indicate that proteins are correctly folded and active. The approach provides a platform amenable to high-throughput structural and functional characterization of a variety of traditionally intractable drug targets.     

Production and partial purification of membrane proteins using a liposome-supplemented wheat cell-free translation system

Background  

Recently, some groups have reported on cell-free synthesis of functional membrane proteins (MPs) in the presence of exogenous liposomes (liposomes). Previously, we reported synthesis of a functional AtPPT1 plant phosphate transporter that was associated with liposomes during translation. However, it is unclear whether or not lipid/MP complex formation is common to all types of MPs in the wheat cell-free system.     

A systematic approach for testing expression of human full-length proteins in cell-free expression systems

Background  

The growing field of proteomics and systems biology is resulting in an ever increasing demand for purified recombinant proteins for structural and functional studies. Here, we show a systematic approach to successfully express a full-length protein of interest by using cell-free and cell-based expression systems.     

Production of serpins using baculovirus expression systems

Headpin is a novel serine proteinase inhibitor (serpin) that is downregulated in many established HNSCC tumor cell lines and human oral SCC specimens. The use of the bacterial and yeast expression systems for headpin resulted in poor yields and proteins with low inhibitory activity. To circumvent these problems, we have developed a baculovirus-insect cell system for high-yield expression as well as fully functional protein. Here, we describe the strategies and methods used to express headpin in an insect cell heterologous system. In addition, procedures to purify the recombinant proteins are described. A metal affinity column followed by a gel-filtration chromatography provides a rapid and efficient method for large quantity preparation of headpin. This method should be useful as an alternative expression system for those serpins that are not purifiable when expressed using the Escherichia coli or yeast expression system.     

Production of serpins using yeast expression systems

Serpins occupy a unique niche in the field of biology. As more of them are discovered, the need to produce sufficient quantities of each to aid experimental and therapeutic research increases. Yeast expression systems are well suited for the production of recombinant serpins. The genetics of many yeast species is well understood and readily manipulated to induce the targeted over-production of many different serpins. In addition, protease-deficient strains of certain species are available and a few species carry out post-translational modifications resembling those of humans. Yeasts are easy to grow and multiply readily in simple culture media hence the cost of production is low, while the scale of production can be small or large. The disadvantages are the inability of most yeast(s) to perform complex post-translational modifications and a lower product yield of secreted protein compared to intracellular protein production. However, for the intracellular production of serpins, in particular the clade B serpins that do not have complex post-translational modifications, yeast expression systems should be among the first systems considered.     

Characterization of presenilin-amyloid precursor interaction using bacterial expression and two-hybrid systems for human membrane proteins

An Escherichia coli system was used to produce the human membrane proteins presenilin 1 and amyloid precursor protein and to analyse their interaction. Our data indicate that the main binding site for amyloid precursor protein is located in the N-terminal three-transmembrane segments of presenilin and not in the proposed active site containing the two conserved aspartate residues. The data also suggest the presence of an additional segment of sufficient hydrophobicity at the C-terminus of PS1 to act potentially as a transmembrane segment. The implications of these findings for the function of γ-secretase are discussed.     

Characterization of presenilin-amyloid precursor interaction using bacterial expression and two-hybrid systems for human membrane proteins

An Escherichia coli system was used to produce the human membrane proteins presenilin 1 and amyloid precursor protein and to analyse their interaction. Our data indicate that the main binding site for amyloid precursor protein is located in the N-terminal three-transmembrane segments of presenilin and not in the proposed active site containing the two conserved aspartate residues. The data also suggest the presence of an additional segment of sufficient hydrophobicity at the C-terminus of PS1 to act potentially as a transmembrane segment. The implications of these findings for the function of gamma-secretase are discussed.     

Expression screening of membrane proteins with cell-free protein synthesis

Detailed biophysical studies of integral membrane proteins are often hampered by sample preparation difficulties. Membrane proteins are typically difficult to express in sufficient amounts to enable the use of demanding techniques such as nuclear magnetic resonance and X-ray crystallography for structural biology. Here, we show that an inexpensive batch-based cell-free expression system can be a viable alternative for production of a wide range of different membrane proteins, both of prokaryotic and eukaryotic origin. Out of 38 tested protein constructs, 37 express at levels suitable for structural biology, i.e. enough to produce several milligrams of protein routinely and without excessive costs. This success rate was not anticipated and is even more impressive considering that more than half of the expressed proteins where of mammalian origin. A detergent screen identified Brij-58 as the, in general, most successful choice for co-translational solubilization of the expressed proteins.     

Synthesis and site-directed fluorescence labeling of azido proteins using eukaryotic cell-free orthogonal translation systems

Eukaryotic cell-free systems based on wheat germ and Spodoptera frugiperda insect cells were equipped with an orthogonal amber suppressor tRNA–synthetase pair to synthesize proteins with a site-specifically incorporated p-azido-l-phenylalanine residue in order to provide their chemoselective fluorescence labeling with azide-reactive dyes by Staudinger ligation. The specificity of incorporation and bioorthogonality of labeling within complex reaction mixtures was shown by means of translation and fluorescence detection of two model proteins: β-glucuronidase and erythropoietin. The latter contained the azido amino acid in proximity to a signal peptide for membrane translocation into endogenous microsomal vesicles of the insect cell-based system. The results indicate a stoichiometric incorporation of the azido amino acid at the desired position within the proteins. Moreover, the compatibility of cotranslational protein translocation, including glycosylation and amber suppression-based incorporation of p-azido-l-phenylalanine within a cell-free system, is demonstrated. The presented approach should be particularly useful for providing eukaryotic and membrane-associated proteins for investigation by fluorescence-based techniques.     

Preparative scale cell-free expression systems: new tools for the large scale preparation of integral membrane proteins for functional and structural studies

Cell-free expression techniques have emerged as promising tools for the production of membrane proteins for structural and functional analysis. Elimination of toxic effects and a variety of options to stabilize the synthesized proteins enable the synthesis of otherwise difficult to obtain proteins. Modifications in the reaction design result in preparative scale production rates of cell-free reactions and yield in milligram amounts of membrane proteins per one millilitre of reaction volume. A diverse selection of detergents can be supplied into the reaction system without inhibitory effects to the translation machinery. This offers the unique opportunity to produce a membrane protein directly into micelles of a detergent of choice. We present detailed protocols for the cell-free production of membrane proteins in different modes and we summarize the current knowledge of this technique. A special emphasize will be on the production of soluble and functionally folded membrane proteins in presence of suitable detergents. In addition, we will highlight the advantages of cell-free expression for the structural analysis of membrane proteins especially by liquid state nuclear magnetic resonance spectroscopy and we will discuss new strategies for structural approaches.     

Wheat germ systems for cell-free protein expression

Cell-free protein expression plays an important role in biochemical research. However, only recent developments led to new methods to rapidly synthesize preparative amounts of protein that make cell-free protein expression an attractive alternative to cell-based methods. In particular the wheat germ system provides the highest translation efficiency among eukaryotic cell-free protein expression approaches and has a very high success rate for the expression of soluble proteins of good quality. As an open in vitro method, the wheat germ system is a preferable choice for many applications in protein research including options for protein labeling and the expression of difficult-to-express proteins like membrane proteins and multiple protein complexes. Here I describe wheat germ cell-free protein expression systems and give examples how they have been used in genome-wide expression studies, preparation of labeled proteins for structural genomics and protein mass spectroscopy, automated protein synthesis, and screening of enzymatic activities. Future directions for the use of cell-free expression methods are discussed.     

High-throughput cell-free systems for synthesis of functionally active proteins

Continuous cell-free translation systems with perpetual supply of consumable substrates and removal of reaction products made the process of in vitro synthesis of individual proteins sustainable and productive. Improvements of cell-free reaction mixtures, including new ways for efficient energy generation, had an additional impact on progress in cell-free protein synthesis technology. The requirement for gene-product identification in genomic studies, the development of high-throughput structural proteomics, the need for protein engineering without cell constraints (including the use of unnatural amino acids), and the need to produce cytotoxic, poorly expressed and unstable proteins have caused increased interest in cell-free protein synthesis technologies for molecular biologists, biotechnologists and pharmacologists.