A novel way to express proline-selectively labeled proteins with a wheat germ cell-free protein synthesis system

For high-throughput protein structural analyses, it is essential to develop a reliable protein overexpression system. Although many protein overexpression systems, such as ones involving Escherichia coli cells, have been developed, the number of overexpressed proteins exhibiting the same biological activities as those of the native ones is limited. A novel wheat germ cell-free protein synthesis system was developed recently, and most of the synthesized proteins that should function in solution were found to be in soluble forms. This suggests the applicability of this protein synthesis method to determination of the functional structures of soluble proteins. In our previous work, we developed a selective labeling technique for amino acids having amide functional groups (other than proline residues) involving the use of several inhibitors for transaminases. This paper in turn describes a proline-selective labeling technique. Based on our results, we have succeeded in constructing a complete amino acid selective labeling technique for the wheat germ cell-free protein synthesis system.     

A wheat germ cell-free system is a novel way to screen protein folding and function

For high-throughput protein structural analysis, it is indispensable to develop a reliable protein overexpression system. Although many protein overexpression systems, such as that involving Escherichia coli cells, have been developed, the number of overexpressed proteins showing the same biological activities as those of the native proteins is limited. A novel wheat germ cell-free protein synthesis system was developed recently, and most of the proteins functioning in solution were synthesized as soluble forms. This suggests the applicability of this protein synthesis method to determination of the solution structures of functional proteins. To examine this possibility, we have synthesized two (15)N-labeled proteins and obtained (1)H-(15)N HSQC spectra for them. The structural analysis of these proteins has already progressed with an E. coli overexpression system, and (1)H-(15)N HSQC spectra for biologically active proteins have already been obtained. Comparing the spectra, we have shown that proteins synthesized with a wheat germ cell-free system have the proper protein folding and enough biological activity. This is the first experimental evidence of the applicability of the wheat germ cell-free protein synthesis system to high-throughput protein structural analysis.     

Automated system for high-throughput protein production using the dialysis cell-free method

High-throughput protein production systems have become an important issue, because protein production is one of the bottleneck steps in large-scale structural and functional analyses of proteins. We have developed a dialysis reactor and a fully automated system for protein production using the dialysis cell-free synthesis method, which we previously established to produce protein samples on a milligram scale in a high-throughput manner. The dialysis reactor was designed to be suitable for an automated system and has six dialysis cups attached to a flat dialysis membrane. The automated system is based on a Tecan Freedom EVO 200 workstation in a three-arm configuration, and is equipped with shaking incubators, a vacuum module, a robotic centrifuge, a plate heat sealer, and a custom-made tilting carrier for collection of reaction solutions from the flat-bottom cups with dialysis membranes. The consecutive process, from the dialysis cell-free protein synthesis to the partial purification by immobilized metal affinity chromatography on a 96-well filtration plate, was performed within ca. 14 h, including 8 h of cell-free protein synthesis. The proteins were eluted stepwise in a high concentration using EDTA by centrifugation, while the resin in the filtration plate was washed on the vacuum manifold. The system was validated to be able to simultaneously and automatically produce up to 96 proteins in yields of several milligrams with high well-to-well reliability, sufficient for structural and functional analyses of proteins. The protein samples produced by the automated system have been utilized for NMR screening to judge the protein foldedness and for structure determinations using heteronuclear multi-dimensional NMR spectroscopy. The automated high-throughput protein production system represents an important breakthrough in the structural and functional studies of proteins and has already contributed a massive amount of results in the structural genomics project at the RIKEN Structural Genomics/Proteomics Initiative (RSGI).     

Printing protein arrays from DNA arrays

We describe a method, DNA array to protein array (DAPA), which allows the 'printing' of replicate protein arrays directly from a DNA array template using cell-free protein synthesis. At least 20 copies of a protein array can be obtained from a single DNA array. DAPA eliminates the need for separate protein expression, purification and spotting, and also overcomes the problem of long-term functional storage of surface-bound proteins.     

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.     

A novel cell-free protein synthesis system

An efficient cell-free protein synthesis system has been developed using a novel energy-regenerating source. Using the new energy source, 3-phosphoglycerate (3-PGA), protein synthesis continues beyond 2 h. In contrast, the reaction rate slowed down considerably within 30–45 min using a conventional energy source, phosphoenol pyruvate (PEP) under identical reaction conditions. This improvement results in the production of twice the amount of protein obtained with PEP as an energy source. We have also shown that Gam protein of phage lambda, an inhibitor of RecBCD (ExoV), protects linear PCR DNA templates from degradation in vitro. Furthermore, addition of purified Gam protein in extracts of Escherichia coli BL21 improves protein synthesis from PCR templates to a level comparable to plasmid DNA template. Therefore, combination of these improvements should be amenable to rapid expression of proteins in a high-throughput manner for proteomics and structural genomics applications.     

Cell-free identification of novel N-myristoylated proteins from complementary DNA resources using bioorthogonal myristic acid analogues

To establish a non-radioactive, cell-free detection system for protein N-myristoylation, metabolic labeling in a cell-free protein synthesis system using bioorthogonal myristic acid analogues was performed. After Cu(I)-catalyzed azide–alkyne cycloaddition (CuAAC) with a biotin tag, the tagged proteins were separated by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) and blotted on a polyvinylidene fluoride (PVDF) membrane, and then protein N-myristoylation was detected by enhanced chemiluminescence (ECL) using horseradish peroxidase (HRP)-conjugated streptavidin. The results showed that metabolic labeling in an insect cell-free protein synthesis system using an azide analogue of myristic acid followed by CuAAC with alkynyl biotin was the most effective strategy for cell-free detection of protein N-myristoylation. To determine whether the newly developed detection method can be applied for the detection of novel N-myristoylated proteins from complementary DNA (cDNA) resources, four candidate cDNA clones were selected from a human cDNA resource and their susceptibility to protein N-myristoylation was evaluated using the newly developed strategy. As a result, the products of three cDNA clones were found to be novel N-myristoylated protein, and myristoylation-dependent specific intracellular localization was observed for two novel N-myristoylated proteins. Thus, the metabolic labeling in an insect cell-free protein synthesis system using bioorthogonal azide analogue of myristic acid was an effective strategy to identify novel N-myristoylated proteins from cDNA resources.     

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.     

Expression,stabilization and purification of membrane proteins via diverse protein synthesis systems and detergents involving cell-free associated with self-assembly peptide surfactants

G-protein coupled receptors (GPCRs) are involved in regulating most of physiological actions and metabolism in the bodies, which have become most frequently addressed therapeutic targets for various disorders and diseases. Purified GPCR-based drug discoveries have become routine that approaches to structural study, novel biophysical and biochemical function analyses. However, several bottlenecks that GPCR-directed drugs need to conquer the problems including overexpression, solubilization, and purification as well as stabilization. The breakthroughs are to obtain efficient protein yield and stabilize their functional conformation which are both urgently requiring of effective protein synthesis system methods and optimal surfactants. Cell-free protein synthesis system is superior to the high yields and post-translation modifications, and early signs of self-assembly peptide detergents also emerged to superiority in purification of membrane proteins. We herein focus several predominant protein synthesis systems and surfactants involving the novel peptide detergents, and uncover the advantages of cell-free protein synthesis system with self-assembling peptide detergents in purification of functional GPCRs. This review is useful to further study in membrane proteins as well as the new drug exploration.     

A novel way of amino acid-specific assignment in 1H-15N HSQC spectra with a wheat germ cell-free protein synthesis system

For high-throughput protein structural analyses, it is indispensable to develop a reliable protein overexpression system. Although many protein overexpression systems, such as ones utilizing E. coli cells, have been developed, a lot of proteins functioning in solution still were synthesized as insoluble forms. Recently, a novel wheat germ cell-free protein synthesis system was developed, and many of such proteins were synthesized as soluble forms. This means that the applicability of this protein synthesis method to determination of the functional structures of soluble proteins. In our previous work, we synthesized (15)N-labeled proteins with this wheat germ cell-free system, and confirmed this applicability on the basis of the strong similarity between the (1)H-(15)N HSQC spectra for native proteins and the corresponding ones for synthesized ones.In this study, we developed a convenient and reliable method for amino acid selective assignment in (1)H-(15)N HSQC spectra of proteins, using several inhibitors for transaminases and glutamine synthase in the process of protein synthesis. Amino acid selective assignment in (1)H-(15)N HSQC spectra is a powerful means to monitor the features of proteins, such as folding, intermolecular interactions and so on. This is also the first direct experimental evidence of the presence of active transaminases and glutamine synthase in wheat germ extracts.     

In situ synthesis of protein arrays

In situ or on-chip protein array methods use cell free expression systems to produce proteins directly onto an immobilising surface from co-distributed or pre-arrayed DNA or RNA, enabling protein arrays to be created on demand. These methods address three issues in protein array technology: (i) efficient protein expression and availability, (ii) functional protein immobilisation and purification in a single step and (iii) protein on-chip stability over time. By simultaneously expressing and immobilising many proteins in parallel on the chip surface, the laborious and often costly processes of DNA cloning, expression and separate protein purification are avoided. Recently employed methods reviewed are PISA (protein in situ array) and NAPPA (nucleic acid programmable protein array) from DNA and puromycin-mediated immobilisation from mRNA.     

Cell-free synthesis of membrane subunits of ATP synthase in phospholipid bicelles: NMR shows subunit a fold similar to the protein in the cell membrane

NMR structure determination of large membrane proteins is hampered by broad spectral lines, overlap, and ambiguity of signal assignment. Chemical shift and NOE assignment can be facilitated by amino acid selective isotope labeling in cell-free protein synthesis system. However, many biological detergents are incompatible with the cell-free synthesis, and membrane proteins often have to be synthesized in an insoluble form. We report cell-free synthesis of subunits a and c of the proton channel of Escherichia coli ATP synthase in a soluble form in a mixture of phosphatidylcholine derivatives. In comparison, subunit a was purified from the cell-free system and from the bacterial cell membranes. NMR spectra of both preparations were similar, indicating that our procedure for cell-free synthesis produces protein structurally similar to that prepared from the cell membranes.     

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.     

无细胞蛋白质芯片的制备及其应用

蛋白质芯片是生物技术和功能蛋白组学的关键技术之一. 传统的生产蛋白的方 法周期长且费用高. 无细胞蛋白质合成系统和蛋白芯片的结合, 避免了基因的克隆、 蛋白的表达、纯化和保存等繁琐过程, 使整个无细胞蛋白芯片的制备过程快捷、迅速 和高效. 本文详细综述了无细胞蛋白质合成系统及其分类、无细胞表达系统在制备蛋 白质芯片方面的研究进展, 并探讨了无细胞蛋白质芯片在蛋白组学研究中的最新应用.     

A novel protein programmed by the mRNA conserved in dry wheat embryos. The principal site of cysteine incorporation during early germination

If bulk mRNA from dry wheat embryos (wheat germ) is used to direct cell-free incorporation of [35S]cysteine into proteins, a striking proportion of the total radioactivity is channeled into a single protein. During early postimbibition development, when protein synthesis is directed by the mRNA conserved in dry embryos, incorporation of cysteine is preponderantly (20-25%) directed into synthesis of this one protein: the 'early' cysteine-labeled protein (Ec). When conserved mRNA from the dry embryos has been fully degraded, as when cellular or cell-free protein synthesis is directed by the mRNA in germinated embryos, synthesis of Ec is not detected. Reliable detection of Ec requires prior alkylation of wheat embryo proteins, and it was especially interesting to find that when wheat embryo proteins are alkylated by iodo[14C]acetamide, two proteins co-dominate the distribution of radioalkylated products in dodecylsulphate/polyacrylamide gels: Ec and wheat germ agglutinin. Using co-electrophoresis with the isotopically labeled protein to detect a dye-staining counterpart, Ec has been purified by combined cation-exchange and gel-filtration chromatography of alkylated wheat germ proteins. The purified protein can be recovered in milligram quantity (5-10 mg/100 g wheat germ) and compositional analysis shows that it is unusually rich in cysteine (approx. 15%) and glycine (approx. 17%), as is wheat germ agglutinin.     

Purification and properties of a translation inhibitor from wheat germ.

A translation inhibitor from wheat germ has been purified more than 400-fold to apparent homogeneity. The inhibitor is a basic protein with a molecular weight of 30 000. This protein effectively blocks protein synthesis in animal cell-free extracts but does not affect protein synthesis in intact cells. Inhibition occurs at a ribosome to inhibitor molar ratio of 100:1, indicating an enzymic mechanism of action. The wheat germ protein inhibits the translation of endogenous mRNA, exogenous mRNA, and poly(uridylic acid) at a step in polypeptide chain elongation and without breakdown of the polysomes. Neither the aminoacylation reaction nor mRNA degradation is affected by the inhibitor. An interesting feature of the inhibition reaction is that it requires, in addition to the wheat germ inhibitor, both ATP and tRNA. The function of these two compounds in the inhibition is presently unknown since neither the hydrolysis of the beta,gamma-pyrophosphate bond of ATP nor a modification of the tRNA can be demonstrated during the reaction.