A picoliter chamber array for cell-free protein synthesis

The completion of human genome sequencing has shifted the focus of research from genes to proteins. In this regard, a protein library chip has become a useful tool for cell-free protein synthesis. In this study, we attempted to make a highly-integrated protein chip from a DNA library using in vitro protein synthesis on a microchamber array fabricated by using PDMS (polydimethyl siloxane), a hydrophobic surface, and glass, a hydrophilic bottom substrate. These structural properties prevented cross-contamination among the chambers. The minimum volume capacity of the smallest chamber was about 1 pl. The total number of chambers per chip was 10,000 on one chip (capacity 150 pl) and 250,000 on two others (1 and 5 pl). Next, we attempted in vitro protein synthesis using this microchamber array. The fluorescence of Green Fluorescent Protein (GFP) expressed on the chamber was rapidly detected (within just 1 h). GFP expression was also successful using immobilized DNA molecules on polymer beads. DNA immobilized beads were added as the source to each microchamber. Protein was successfully synthesized from DNA immobilized beads, which allowed easy handling of the DNA molecules.     

Cell-free production of aggregation-prone proteins in soluble and active forms

We have developed an efficient cell-free protein synthesis system for the production of soluble and active eukaryotic proteins that are predominantly produced as inclusion bodies in bacteria. S30 extracts (indicating the supernatant of cell homogenate when centrifuged at 30,000g) for cell-free protein synthesis were prepared from Escherichia coli that was modified to overexpress a set of chaperones (GroEL/ES or DnaK/J-GrpE) and disulfide isomerase (leader sequence-free mature DsbC expressed in the cytoplasm). The solubility and biological activity concentration (biological activity per unit volume of cell-free protein synthesis reaction mixture) of the protein synthesized by the new cell-free protein synthesis system showed a dramatic improvement. Solubility enhancement was most dramatic with the existence of DnaK/J-GrpE. It shows that the co-translational interaction with DnaK/J-GrpE prior to folding trial is important in maintenance of the aggregation-prone protein in a folding-competent soluble state. For maximizing the biological activity concentration of the expressed protein, the additional presence of GroEL/ES and DsbC was required. When human erythropoietin was expressed in the developed cell-free protein synthesis system including endogenously overexpressed chaperones and/or DsbC, the biological activity concentration of erythropoietin was enhanced by 700%. It implies that the post-translational folding and disulfide bond reshuffling as well as co-translational folding are important in acquiring functionally active protein from cell-free expression system. This is the first report of using S30 extracts including endogenously overexpressed chaperones and/or disulfide isomerase for the efficient production of soluble and active proteins in cell-free protein synthesis. This new cell-free protein synthesis system was capable of introducing much larger amounts of chaperones and disulfide isomerase compared to a conventional method that supplements them separately. The developed cell-free protein synthesis system supported efficient expression of the eukaryotic proteins in soluble and active forms without the need of any exogenous addition or coexpression of folding effectors.     

In situ protein microarrays capable of real-time kinetics analysis based on surface plasmon resonance imaging

In recent years, in situ protein synthesis microarray technologies have enabled protein microarrays to be created on demand just before they are needed. In this paper, we utilized the TUS-TER immobilization technology to allow label-free detection with real-time kinetics of protein–protein interactions using surface plasmon resonance imaging (SPRi). We constructed an expression-ready plasmid DNA with a C-terminal TUS fusion tag to directionally immobilize the in situ synthesized recombinant proteins onto the surface of the biosensor. The expression plasmid was immobilized on the polyethylene imine-modified gold surface, which was then coupled with a cell-free expression system on the flow cell of the SPRi instrument. The expressed TUS fusion proteins bind on the surface via the immobilized TER DNA sequence with high affinity (∼3–7 × 10⁻¹³ M). The expression and immobilization of the recombinant in situ expressed proteins were confirmed by probing with specific antibodies. The present study shows a new low cost method for in situ protein expression microarrays that has the potential to study the kinetics of protein–protein interactions. These protein microarrays can be created on demand without the problems of stability associated with protein arrays used in the drug discovery and biomarker discovery fields.     

Streamlined cell-free protein synthesis from sequence information

In this study, we describe a cell-free protein synthesis consolidated with polymerase chain reaction (PCR)-based synthetic gene assembly that allows for streamlined translation of genetic information. In silico-designed fragments of target genes were PCR-assembled and directly expressed in a cell-free synthesis system to generate functional proteins. This method bypasses the procedures required in conventional cell-based gene expression methods, integrates gene synthesis and cell-free protein synthesis, shortens the time to protein production, and allows for facile regulation of gene expression by manipulating the oligomer sequences used for gene synthesis. The strategy proposed herein expands the flexibility and throughput of the protein synthesis process, a fundamental component in the construction of synthetic biological systems.     

Solid-phase translation and RNA–protein fusion: a novel approach for folding quality control and direct immobilization of proteins using anchored mRNA

A novel cell-free translation system is described in which template-mRNA molecules were captured onto solid surfaces to simultaneously synthesize and immobilize proteins in a more native-state form. This technology comprises a novel solid-phase approach to cell-free translation and RNA–protein fusion techniques. A newly constructed biotinylated linker-DNA which enables puromycin-assisted RNA–protein fusion is ligated to the 3′ ends of the mRNA molecules to attach the mRNA-template on a streptavidin-coated surface and further to enable the subsequent reactions of translation and RNA–protein fusion on surface. The protein products are therefore directly immobilized onto solid surfaces and furthermore were discovered to adopt a more native state with proper protein folding and superior biological activity compared with conventional liquid-phase approaches. We further validate this approach via the production of immobilized green fluorescent protein (GFP) on microbeads and by the production and assay of aldehyde reductase (ALR) enzyme with 4-fold or more activity. The approach developed in this study may enable to embrace the concept of the transformation of ‘RNA chip-to-protein chip’ using a solid-phase cell-free translation system and thus to the development of high-throughput microarray platform in the field of functional genomics and in vitro evolution.     

Bacterial cell-free system for high-throughput protein expression and a comparative analysis of Escherichia coli cell-free and whole cell expression systems

Sixty-three proteins of Pseudomonas aeruginosa in the size range of 18-159 kDa were tested for expression in a bacterial cell-free system. Fifty-one of the 63 proteins could be expressed and partially purified under denaturing conditions. Most of the expressed proteins showed yields greater than 500 ng after a single affinity purification step from 50 microl in vitro protein synthesis reactions. The in vitro protein expression plus purification in a 96-well format and analysis of the proteins by SDS-PAGE were performed by one person in 4 h. A comparison of in vitro and in vivo expression suggests that despite lower yields and less pure protein preparations, bacterial in vitro protein expression coupled with single-step affinity purification offers a rapid, efficient alternative for the high-throughput screening of clones for protein expression and solubility.     

Solid-phase translation and RNA-protein fusion: a novel approach for folding quality control and direct immobilization of proteins using anchored mRNA

A novel cell-free translation system is described in which template-mRNA molecules were captured onto solid surfaces to simultaneously synthesize and immobilize proteins in a more native-state form. This technology comprises a novel solid-phase approach to cell-free translation and RNA-protein fusion techniques. A newly constructed biotinylated linker-DNA which enables puromycin-assisted RNA-protein fusion is ligated to the 3' ends of the mRNA molecules to attach the mRNA-template on a streptavidin-coated surface and further to enable the subsequent reactions of translation and RNA-protein fusion on surface. The protein products are therefore directly immobilized onto solid surfaces and furthermore were discovered to adopt a more native state with proper protein folding and superior biological activity compared with conventional liquid-phase approaches. We further validate this approach via the production of immobilized green fluorescent protein (GFP) on microbeads and by the production and assay of aldehyde reductase (ALR) enzyme with 4-fold or more activity. The approach developed in this study may enable to embrace the concept of the transformation of 'RNA chip-to-protein chip' using a solid-phase cell-free translation system and thus to the development of high-throughput microarray platform in the field of functional genomics and in vitro evolution.     

Effect of energy source on the efficiency of translational termination during cell-free protein synthesis

We studied how the fidelity of translation termination is affected by the method of ATP regeneration during cell-free protein synthesis. During the in vivo expression of hEPO, whose termination is directed by the UGA codon, we found that substantial proportions of the translational products showed a larger molecular weight than expected. Similar results were obtained in a cell-free synthesis reaction using phosphoenol pyruvate (PEP) or 3-phosphoglycerate (3PG) for ATP regeneration. However, when the energy source was switched to creatine phosphate (CP), the readthrough of the UGA codon was completely repressed and only the target protein of the correct size was expressed in a high yield. To the best of our knowledge, this is the first report describing the relationship between the regeneration of nucleotide triphosphates and protein readthrough, and we also believe that the discovery would pave the way to the selective and efficient expression of target proteins in cell-free protein synthesis systems.     

Direct preparation of giant proteo-liposomes by in vitro membrane protein synthesis

We investigated the direct constitution of membrane proteins into giant liposomes in cell-free (in vitro) protein synthesis. Giant liposomes were present in a translation reaction cocktail of a wheat germ cell-free protein translation system. Apo cytochrome b(5) (b5) and its fusion proteins were synthesized and directly localized in the liposomes. After the translation reaction, the proteo-liposomes were isolated by simplified discontinuous density-gradient centrifugation. Apo cytochrome b(5) conjugated dihydrofolate reductase (DHFR) was synthesized in the same procedure and the protein was directly displayed on the liposome surface. b5 acts as a "hydrophobic tag" for recruitment to the liposome surface.     

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.     

On-chip Escherichia coli culture, purification, and detection of expressed proteins

In a recent study, we reported the results of a rapid high-throughput expression analysis of the affinity-tagged proteins present in total cell lysates, using a surface plasmon resonance (SPR) imaging protein chip system. In this paper, we describe a novel method, which is able to sequentially carry out a recombinant Escherichia coli culture, as well as the detection and purification of the expressed proteins on a single microwell chip, fabricated on a two-dimensional thin gold film. Following the induction of the protein on the microwell chip, the E. coli cells were lysed on the chip via the addition of lysozymes, and the expressed glutathione S-transferase-fused green fluorescent protein (GST–GFP) was then purified on the chip via affinity interaction with the glutathionylated gold surface of the chip. Finally, the expressed protein was directly detected using the surface plasmon resonance (SPR) imaging system. This system saves a substantial amount of time, experimental resources, and labor, by allowing for the complicated and labor-intensive procedures inherent to the production of recombinant proteins to be conducted on a single microwell chip, simply and economically.M. Kim and S. Y. Lee contributed equally to this work.     

Surface plasmon resonance imaging-based protein arrays for high-throughput screening of protein-protein interaction inhibitors

The E7 protein produced by high-risk human papillomavirus (HPV) induces a degradation of the retinoblastoma tumor suppressor RB through direct interaction, which suggests that an inhibitor for the interaction can be a potential anticancer drug. A surface plasmon resonance (SPR) imaging-based protein array chip was developed for the high-throughput screening of inhibitor molecules targeting RB-E7 interaction. The glutathione S-transferase-fused E7 protein (GST-E7) was first layered onto a glutathionylated gold chip surface that had been designed to specifically bind to GST-fused proteins. Subsequently, a microarrayer was used to spot the hexa-histidine-tagged RB proteins (His(6)-RB) onto the GST-E7-layered gold chip surface, and the resulting SPR image was analyzed. Upon increased His(6)-RB concentration in the spotting solution, the SPR signal intensity increased proportionally, indicating that His(6)-RB bound to GST-E7 in a concentration-dependent manner. The His(6)-RB/GST-E7 interaction was challenged by spotting the His(6)-RB solution in the presence of a RB binding peptide (PepC) derived from a motif on E7. The SPR imaging data showed that PepC inhibited the His(6)-RB/GST-E7 interaction in a concentration-dependent manner. Our results show that the SPR imaging-based protein array chip can be applied to screen small molecule inhibitors that target protein-protein interaction.     

Cell-free synthesis of recombinant proteins from PCR-amplified genes at a comparable productivity to that of plasmid-based reactions

The functional stability of mRNA is one of the crucial factors affecting the efficiency of cell-free protein synthesis. The importance of the stability of mRNA in the prolonged synthesis of protein molecules becomes even greater when the cell-free protein synthesis is directed by PCR-amplified DNAs, because the linear DNAs are rapidly degraded by the endogenous nucleases and, thus, the continuous generation of mRNA molecules is limited. With the aim of developing a highly efficient cell-free protein synthesis system directed by PCR products, in this study, we describe a systematic approach to enhance the stability of mRNA in cell-free extracts. First, exonuclease-mediated degradation was substantially reduced by introducing a stem-loop structure at the 3'-end of the mRNA. The endonucleolytic cleavage of the mRNA was minimized by using an S30 extract prepared from an Escherichia coli strain that is deficient in a major endonuclease (RNase E). Taken together, through the retardation of the endonucleolytic and exonucleolytic degradations of the mRNA molecules, the level of protein expression from the PCR-amplified DNA templates becomes comparable to that of conventional plasmid-based reactions. The enhanced productivity of the PCR-based cell-free protein synthesis enables the high-throughput generation of protein molecules required for many post-genomic applications.     

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.     

Interactions between peptides containing nucleobase amino acids and T7 phages displaying S. cerevisiae proteins

The importance of high-throughput analyses of protein abundances and functions is interestingly increasing in genomic/proteomic studies. In such postgenome sequencing era, a protein-detecting chip, in which a large number of molecules specifically capturing target proteins (capturing agents) such as antibodies, recombinant proteins, and small molecules are arrayed onto solid, wet, or semi-wet substrates, enables comprehensive analysis of proteomes by a single experiment. However, whole proteomes are generally complicated for comprehensive analyses so that alternative approaches to subproteome analysis categorized by protein functions and binding properties (focused proteome) would be effective. Approaching the goal of development of designed peptide chip for protein analysis, diversity increases in peptide structures and validation of target proteins are needed. We herein describe design and synthesis of nucleobase amino acid (NBA)-containing peptides, selection of nucleic acid-related proteins derived from S. cerevisiae, and detection of interactions between NBA-containing peptides and T7 phages displaying proteins by both enzyme-linked immunosorbent assays (ELISA) and label-free anomalous reflection of gold (AR) measurements. Twenty-eight phage clones were obtained by the phage-display method and sequenced. Ten of 28 clones were expected to be nucleic acid-related proteins including initiation factor, TYB protein, ribosomal proteins, elongation factor, ATP synthase subunit, GTP-binding protein, and ribonuclease. Other phage clones encoded several classes of enzymes such as reductase, oxidase, aldolase, metalloprotease, and hexokinase. Both ELISA and AR measurements suggested that the methodology of in vitro selection for recognition of the NBA-containing peptide presented in this study was successfully established. Such a combination of NBA and phage display technologies would be potential to efficiently confirm valuable target proteins binding specifically to capturing agents, to be arrayed onto solid surfaces to develop the designed peptide chip.     

Cell-free synthesis and multifold screening of Candida antarctica lipase B (CalB) variants after combinatorial mutagenesis of hot spots

We have developed a strategy for rapid and combinatorial optimization of the hot spot residues of enzymes. After combinatorial randomization of target locations in the Candida antarctica lipase B (CalB) gene, the individual variant genes isolated in the E.coli cells were expressed in the cell-free protein synthesis system to analyze different parameters of the resulting CalB variants. The enzymatic assays for the hydrolysis of para-nitrophenyl-ester (pNP-ester) and triglyceride, synthesis of wax ester, and thermal stability of the variant enzymes were carried out simultaneously in 96-well microtiter plates. From the 1,000 variant genes tested in each assay, we were able to identify a series of the variant enzymes having markedly improved hydrolytic, synthetic activity, or thermal stability. The improved traits of the cell-free selected CalB variants were well reproduced when the corresponding genes were expressed in Pichia pastoris. Therefore, we expect that the proposed strategy of cell-free expression screening can serve as a viable option for rapid and precise tuning of enzyme molecules, not only for analytical purposes but also for industrial applications through large scale production using microbial cells transformed with variant genes selected from the cell-free expression screening.     

Cell-free protein synthesis for proteomics.

The use of cell-free expression systems as an alternative to cell-based methods for protein production is greatly facilitating studies of protein functions. Recent improvements to cell-free systems, and the development of cell-free protein display and microarray technologies, have led to cell-free protein synthesis becoming a powerful tool for large-scale analysis of proteins. This paper reviews the most commonly used cell-free systems and their applications in proteomics.