JP4561243B2 - Medium for cell-free protein synthesis system - Google Patents

Description

  The present invention relates to a medium for a cell-free protein synthesis system and use thereof.

  Searching for useful proteins such as enzymes using nucleic acids collected from various organisms, and searching for new useful substances using these proteins have been underway. It has also been promoted to artificially synthesize new proteins to improve their functions or develop new functions. In order to advance these research and development efficiently, a system for efficiently synthesizing proteins is necessary. Moreover, it is preferable that the obtained protein has a three-dimensional structure that should be inherent. Therefore, a system for producing a protein having an effective three-dimensional structure with high efficiency is required.

As such a system, utilization of a cell-free protein synthesis system is expected. Currently, cell-free protein synthesis systems are roughly classified into a system using an E. coli extract and a system using a eukaryotic cell extract such as wheat germ. In general, effective folding of proteins is possible in eukaryotic systems, but is considered extremely difficult in prokaryotic systems such as E. coli. This is because in a system using E. coli, foreign proteins synthesized in cells are likely to aggregate in the cells, and it is necessary to resolubilize the aggregated proteins to give a functioning three-dimensional structure. Furthermore, for such conformation control, it is necessary to examine the choice of chaperone protein, reaction conditions, and the like, but such a condition study is difficult and does not always succeed.

In order to solve such problems, there is an attempt to co-express a plurality of chaperone proteins that assist the folding of proteins such as DnaK, DnaJ, and GrpE together with the target protein in an E. coli extract (Patent Document 1). There is also an attempt to use an extract of Escherichia coli in which the chaperone protein is expressed after heat shock is applied to Escherichia coli to induce the expression of the chaperone protein (Patent Document 2).
JP 2002-335959 A JP 7-194374 A

  However, even if chaperone expression is induced by heat shock or the like, functional proteins are not produced so efficiently, and active proteins cannot be synthesized efficiently. On the other hand, even in a eukaryotic cell system such as wheat germ extract, the probability of actually synthesizing a protein having an effective three-dimensional structure is not necessarily high, and is still difficult. Furthermore, eukaryotic cell systems inherently have the disadvantage that it takes time to synthesize proteins. From the above, the present situation is that the synthesis of a protein with an effective three-dimensional structure has not been achieved.

  Accordingly, an object of the present invention is to provide a medium for a cell-free protein synthesis system suitable for efficiently producing a protein with an effective three-dimensional structure. Another object of the present invention is to provide a method for efficiently producing a protein having an effective three-dimensional structure.

  The present inventors paid attention to a cell-free protein synthesis system using a cell-free extract of Escherichia coli. The present inventors have studied various techniques for promoting efficient protein folding in this system. As a result, the cells were transformed by introducing DNA encoding a folding auxiliary protein such as chaperone, and the transformant was cultured. By using the cell-free extract obtained as described above, it was found that a protein having a highly efficient and effective three-dimensional structure can be synthesized even in a cell-free extraction system, and the present invention has been completed. According to the present invention, the following means are provided.

  According to one aspect of the present invention, a cell for a cell-free protein synthesis system, in which the expression ability of one or more folding auxiliary proteins is activated or imparted by genetic recombination There is provided a medium containing a fraction comprising the auxiliary protein therein. In this medium, the folding auxiliary protein is preferably selected from the Hsp70 family, the Hsp60 family and a protein family related to disulfide bond formation, and the folding auxiliary protein is DnaK, DnaJ, GrpE, GroES and GroEL. Is preferably selected from.

  In any of these cell-free protein synthesis media, it is preferable that the fraction contains an intracellular translation factor. In any of these media, the target protein to be synthesized can be a multimeric protein or a protein having a disulfide bond. In any of these media, the cells are preferably Escherichia coli or yeast. The medium for the cell-free protein synthesis system may include a cell extract in which the expression ability of the folding auxiliary protein is activated or imparted by gene recombination.

  In another embodiment of the present invention, there is provided a method for producing a protein, comprising the step of synthesizing a protein using any one of the above-described media for a cell-free protein synthesis system. In the synthesis step of this method, the medium may contain protein disulfide isomerase and / or thioredoxin. The synthesis step is preferably performed within 3 hours.

Furthermore, according to another aspect of the present invention, there is provided a method for producing a medium for a cell-free protein synthesis system, wherein the expression ability of one or more folding auxiliary proteins is activated by genetic recombination. Culturing cultured or applied cells, and collecting a fraction containing at least a translation factor and the folding auxiliary protein in the cultured cells,
A method is provided comprising: In this method, the cell is transformed by introducing into the cell a polynucleotide encoding a folding auxiliary protein selected from the Hsp70 family, the Hsp60 family, and a protein family related to disulfide bond formation. It is a preferable aspect that it is a body. In these methods, it is preferable to carry out the collection step without causing a reducing agent to act on the fraction. Moreover, according to this form, the medium for a cell-free protein synthesis system obtained by the method in any one of these is provided.

  According to another embodiment of the present invention, there is also provided a cell-free protein synthesis system kit comprising a medium for any of the above cell-free protein synthesis systems. Furthermore, according to another embodiment of the present invention, in order to produce a medium for a cell-free protein synthesis system, which is a cell in which the expression ability of a folding auxiliary protein is activated or imparted by genetic recombination. Cells are provided. According to yet another embodiment, there is provided a protein screening method comprising the step of synthesizing a target protein using any one of the above-described media for a cell-free protein synthesis system, and the synthesized target protein. Confirming whether or not the device has a function corresponding to the purpose to be screened.

  The medium for cell-free protein synthesis system of the present invention (hereinafter simply referred to as protein synthesis medium) has been activated or imparted with the ability to express one or more folding auxiliary proteins by genetic recombination. It contains a fraction containing the auxiliary protein in the cell. The protein production method of the present invention is characterized by using such a protein synthesis medium. By using the protein synthesis medium of the present invention, it is possible to supply a folding auxiliary protein combined in a sufficient amount with a cell-free protein synthesis system, thereby easily synthesizing a protein with an active three-dimensional structure. it can. That is, at the same time, the protein can be obtained in an efficiently solubilized state. According to the present invention, even a multimeric protein or a protein having a disulfide bond can be obtained having an effective three-dimensional structure.

  Furthermore, the transcription factor and translation factor of the cell are simultaneously expressed in the cell. That is, usually these translation factors and folding auxiliary proteins are simultaneously expressed in the cells and can be fractionated simultaneously from these cells. Therefore, a protein synthesis medium containing a fraction containing at least a translation factor for protein synthesis together with the folding auxiliary protein can be easily obtained. Such protein synthesis media have excellent folding ability or ability to synthesize proteins with an effective three-dimensional structure.

  According to the protein synthesis medium of the present invention, the operation of separately preparing a folding auxiliary protein and adding it to a cell-free protein synthesis system can be omitted or simplified, and the folding auxiliary protein can be shared in the protein synthesis system. There is no need for expression. Therefore, according to the protein synthesis medium of the present invention, it is possible to easily construct a cell-free protein synthesis system having high folding ability or protein synthesis ability with an effective three-dimensional structure. In addition, the protein synthesis medium of the present invention can contribute to highly efficiently synthesizing a target protein, and can express and identify many proteins, screen their functions, or have a physiological activity on proteins. It is preferably used for screening a substance.

  Hereinafter, the protein synthesis medium of the present invention will be described, and the preparation of the protein synthesis medium and the production of the protein using the protein synthesis medium will be described.

(Protein synthesis medium and preparation thereof)
The protein synthesis medium includes at least a part of a cell extract in which the expression ability of one or more folding auxiliary proteins is activated or imparted by genetic recombination. The cell to be used is not particularly limited. For example, Escherichia coli, yeast, plant seed cells, mammalian reticulocyte cells and the like can be mentioned. Considering the protein synthesis speed, it is preferable to use Escherichia coli, and considering the expression of eukaryotic proteins, yeast is preferable.

  As E. coli, it is preferable not to hold a plasmid, and E. coli derived from K-1 strain is generally used. Preferred plants in the plant seed cells include wheat, barley, rice, corn, and spinach, and particularly preferably wheat. Particularly preferred are those derived from wheat seeds, among which embryos not containing endosperm, especially those derived from wheat germs are preferred. Preferred examples of mammals in mammalian reticulocytes include rabbits, mice, rats, and guinea pigs. Examples of the yeast include sake yeast and wine yeast. Specific examples include yeasts of the genus Saccharomyces such as Saccharomyces cerevisiae and Schizosaccharomyces pombe, and Pichia yeasts such as Pichia pastoris. More preferred are yeasts including Saccharomyces genus such as Saccharomyces cerevisiae.

  Folding auxiliary proteins include all proteins that support protein folding, and include proteins generally called so-called molecular chaperones, chaperones, chaperonins, and the like. Folding auxiliary proteins are also known to be expressed under stress conditions and can be included in the group of heat shock proteins. Therefore, the group of heat shock proteins is also included in the folding auxiliary protein in the present invention.

  Examples of the folding auxiliary protein include proteins classified into the Hsp70 family. Such proteins include DnaK, DnaJ, and GrpE. Proteins classified into the Hsp60 family are also included. Examples of such proteins include GroES and GroEL. Moreover, the protein classified into Hsp90 family may be sufficient. It may be a protein classified into the Hsp100 family. Further, it may be a protein classified into the sHsp family.

  Folding auxiliary proteins also include proteins that are classified into a family of proteins related to disulfide bond formation. Here, “related to disulfide bond formation” means related to cleavage and exchange in addition to disulfide bond formation. Examples thereof include disulfide oxidoreductases such as DsbA, DsbB, DsbC, DsbD, and thioredoxin, and isomerases such as protein disulfide isomerase (PDI). PDI is preferably derived from mold, and PDI disclosed in JP-A-6-38752 is more preferable. As thioredoxin, those derived from eukaryotes such as plants and animals can be used. Examples of the folding auxiliary protein include isomerases such as peptidyl-prolyl-cis / trans-isomerase (PPI).

  In addition, as a folding auxiliary protein, a folding auxiliary protein having the same or similar function as described above can also be used.

  These various folding auxiliary proteins are used alone or in combination of two or more. In the present invention, these folding auxiliary proteins are not co-expressed with the target protein in the protein synthesis medium, but are expressed in the host cell that is the raw material of the protein synthesis medium. Does not compete with target protein production. Therefore, in the present invention, it is easy to express a plurality of types of folding auxiliary proteins simultaneously and in large quantities. For this reason, it is preferable to combine two or more types, more preferably three or more types of folding auxiliary proteins.

  As the folding auxiliary protein, proteins classified into Hsp60 family and Hsp70 family can be preferably used. Specific examples include DnaK, DnaJ, GrpE, GroEL, and GroES. Of these, GroEL and GroES can be preferably used.

  Transcription factors, translation factors, and folding auxiliary proteins are present in cells in which the expression ability of the folding auxiliary protein is activated or imparted by gene recombination. “By genetic recombination” means that various methods for introducing an exogenous polynucleotide into a host cell are used. The exogenous polynucleotide activates or imparts the expression ability of the folding auxiliary protein, such as DNA encoding the folding auxiliary protein, DNA encoding a promoter that enhances the expression of the foreign or endogenous folding auxiliary protein. It is not limited as long as it is an exogenous polynucleotide that contributes to.

  Activation or imparting of the expression ability of the folding auxiliary protein usually depends on the type of host cell such as the polynucleotide encoding the folding auxiliary protein, the promoter that controls transcription of this polynucleotide, the terminator, the selection marker, and the expression form. This is carried out by introducing a polynucleotide construct comprising various polynucleotide factors into a host cell. As the construct for introduction, a conventionally known construct such as a vector can be appropriately selected and used according to the type of cell and the introduction method.

  When Escherichia coli is used as a host, those derived from pBR322, pUC12, pUC13, pUC18, pUC19, pUC118, and pUC119 are preferably used. When yeast is used as the host, those derived from pRS403, pYES2, pSE937, etc. are preferably used.

  When a polynucleotide encoding two or more kinds of folding auxiliary proteins is introduced, these coding regions do not necessarily have to be introduced as one operon (even in a cell that allows an operon). It can also be introduced controllably by individual promoters. The polynucleotide encoding the folding auxiliary protein is preferably under the control of a promoter having strong promoter activity, but may be under the control of an inducible promoter. This is because when the protein is under the control of an inducible promoter, the production amount and type of the folding auxiliary protein can be controlled according to the content of the required protein synthesis medium.

  For example, in order to express a folding auxiliary protein using Escherichia coli as a host, a T7 promoter, a lac promoter, a trp promoter, a recA promoter, a λPL promoter, an araB promoter and the like can be mentioned. Furthermore, an IPTG-inducible lac operator sequence, a tetracycline repressor binding sequence, a catabolite-inducible sequence, and the like can be provided in the vicinity of the promoter region.

  When yeast is used as a host, pyruvate decarboxylase gene promoter (PDC promoter), preferably PDC1 promoter which is a sufficiently strong promoter, alcohol dehydrogenase gene promoter (ADH promoter), preferably ADH1 promoter In addition, hyperosmotic response 7 gene (HOR7 gene), glyceraldehyde 3-phosphate dehydrogenase 2 gene (TDH2 gene), glyceraldehyde triphosphate dehydrogenase 3 (TDH3) gene, glassose monophosphate kinase 1 (GAL1) gene, phosphoglycerate kinase (PGK) gene, TEF gene, cold shock protein gene and heat shock protein gene promoter.

  Whether or not the expression ability of a desired folding assisting protein has been activated or imparted by gene recombination can be confirmed by an ordinary selection method, and cells confirmed thereby can be used.

  In cells thus produced by gene recombination, transcription factors, translation factors and folding auxiliary proteins are produced in the cells. Therefore, the protein synthesis medium of the present invention can be obtained by culturing such cells and fractionating a fraction containing these proteins from the cell extract. As the culture condition, a culture condition according to the type of cell can be employed. For example, the cell can be cultured up to the vicinity of its maximum growth phase. In order to activate a promoter that controls the expression of the folding assisting protein, an external factor such as IPTG can be added to the medium and cultured.

  In order to obtain a protein synthesis medium from cultured cells, the collected cells are crushed by a known method, and a fraction containing at least a folding auxiliary protein is fractionated. Preferably, the fraction containing the translation factor is fractionated at the same time, and the fraction containing the transcription factor is more preferred. By including a translation factor and a transcription factor at the same time, a more preferable protein synthesis medium can be obtained. Note that the folding auxiliary protein, the translation factor, and the like are usually easily and simultaneously extracted from the cell extract. Here, the translation factor includes various factors capable of translating RNA encoding the protein to be synthesized, and the transcription factor is various transcription factors that transcribe a polynucleotide such as DNA encoding the target protein to be synthesized into mRNA. Is included. Examples of factors that can be included in the protein synthesis medium in addition to the folding auxiliary protein include DNA-dependent RNA polymerase, tRNA, aminoacyl RNA synthetase, ribosome, initiation factor, elongation factor, termination factor, and the like.

  In the protein synthesis medium of the present invention, the extracted fractions from transformed cells and non-transformed cells may be appropriately combined. That is, the transcription factor and the folding auxiliary protein may be simultaneously recovered from the cells in which they are co-expressed, but may be separately prepared and mixed. For example, a fraction containing a folding assisting protein is fractionated from cells that have undergone a predetermined genetic recombination, while cells that have not been genetically modified in relation to the expression ability of the folding assisting protein for this fraction It is also possible to fractionate fractions containing translation factors and transcription factors and mix them.

  Folding auxiliary protein, preferably the fraction containing the protein and a translation factor, is usually homogenized by crushing the cells, adding a buffer containing several kinds of salts to solubilize protein components and ribosomes, and then centrifuging. Obtained by a method of precipitating insoluble components by separation and purifying by gel filtration or the like. In addition, a fraction (S30 extract) from E. coli can be obtained by, for example, a known method Zubay, G (Annu. Rev. Genet. : vol. 7, p267-287, 1973; Platt, Coupled transcription- translation in prokaryotic cell-free systems p.179-209 (1984); Hames, BD and Higgins, SJ, Transcription and Translation: A Practical Approach, IRL Press New York; Kudlicki, Anal Biochem206 (2): 389-93 (1992)).

  In preparing such a cell extract, 2-mercaptoethanol, cysteamine, dithiothreitol, glutathione, dithioerythritol, thioglycol are used in order to prevent formation of proteins by suppressing formation of disulfide bonds. A reducing agent containing a free sulfhydryl group such as a rate can be added, but it is not necessary to add it. This is because a protein having a disulfide bond may be efficiently synthesized by preparing a protein synthesis medium without adding it. When these reducing agents are added, during the protein synthesis, these reducing agents are inactivated by neutralizing or removing them by dialysis, etc. to reduce or inactivate their action, thereby forming disulfide bonds. It is possible to promote the formation of an effective three-dimensional structure.

  In addition to the above reducing agent, additional components necessary for protein synthesis can be added to the protein synthesis medium thus obtained as appropriate. As such an additional component, a folding auxiliary protein related to disulfide bond formation such as PDI or thioredoxin may be added. The eukaryotic-derived folding auxiliary protein can be effectively added separately without being co-expressed in the cells as the translation factor supply source. These additional components may be added to the protein synthesis medium in the synthesis step, or may be added after preparation of the protein synthesis medium and included in advance prior to the synthesis step.

  The protein synthesis medium may be stored lyophilized. In lyophilization, polysaccharides such as polyhydric alcohols, trehalose and inositol can be added to maintain the activity of transcription translation factors and folding auxiliary proteins during lyophilization, thawing and storage. . In addition, components necessary for improving storage stability may be added.

  The protein synthesis medium of the present invention contains a folding auxiliary protein expressed together with a transcription factor and a translation factor in a cell in which the expression ability of the folding auxiliary protein is activated or imparted by genetic recombination. Various factors necessary for cell protein synthesis are provided together. Therefore, according to this protein synthesis medium, it is possible to easily obtain a functional protein by avoiding the difficulty of searching for a combination of folding auxiliary proteins for solubilizing the target protein and providing an effective three-dimensional structure. Can do. In addition, the expression of the folding auxiliary protein is highly controllable, and since the folding auxiliary protein was produced in the cells supplying the translation factor prior to the synthesis of the target protein, the final protein synthesis The amount of folding assisting protein in the medium can be arbitrarily set. Therefore, it is a protein synthesis medium containing a sufficient amount of folding auxiliary protein. Further, in the protein synthesis medium of the present invention, since stress such as heat shock is not applied to the cells, it is presumed that the translation factor is not inactivated and has sufficient activity. Although not restrictive, in the protein synthesis medium of the present invention, these translation factors and various folding auxiliary proteins are fractionated from cells at the same time. Guessed.

(Protein production)
In order to produce a protein using such a protein synthesis medium of the present invention, an ordinary cell-free protein synthesis system (in vitro translation system or in vitro transcription / translation system) may be constructed and a synthesis step may be performed. The components necessary for these protein synthesis systems are well known. For example, polynucleotides encoding proteins serving as templates for transcription or translation, various nucleotides, various amino acids, energy sources such as ATP, phosphoenolpyruvate, pyruvate kinase In addition, a metal salt of acetic acid or sulfuric acid, a polymer compound such as polyethylene glycol and dextran, and a reducing agent such as ascorbic acid can be used. The temperature conditions in the synthesis step are not particularly limited, and may be performed under temperature conditions corresponding to the synthesis system to be used.

  The target protein to be synthesized by the present protein synthesis medium is not particularly limited, and may be a known protein, a fusion protein combining known amino acid sequences, or a protein having an artificial amino acid sequence. Such proteins include various enzymes, hormones, various growth factors, hormones and growth factor receptors, antibodies, and regulatory proteins. According to the present protein synthesis medium, aggregation of the protein synthesized in the cell-free protein synthesis system can be suppressed, or the aggregation state of the aggregated protein can be loosened to solubilize the protein.

  The target protein is preferably a multimeric protein or a protein having a disulfide bond as a target protein. This is because these proteins are generally difficult to solubilize and do not express their original functions unless an appropriate three-dimensional structure can be formed. According to the present protein synthesis medium, since it contains an effective amount of folding auxiliary protein, when one of the folding auxiliary proteins contains a protein selected from a family of proteins related to disulfide bond formation, disulfide Proteins with bonds can be easily synthesized. In addition, as long as the protein which exhibits the original function is provided, the disulfide bond in the protein provided with a disulfide bond may be intramolecular or intermolecular. Examples of the protein having a disulfide bond include insulin, α-chymotrypsin, an antibody in which an intermolecular disulfide bond is formed between the L chain and the H chain, peroxidase such as hemoglobin, hemocyanin, manganese peroxidase, cytochrome C peroxidase, and lignin peroxidase. Metal-containing proteins, reductases such as NOx reductase, trypsin, cellulase and the like.

  The polynucleotide serving as a template for the synthesis of the target protein may be RNA or DNA, and is appropriately selected depending on the type of synthesis system and the like. These templates may be linear such as PCR products or circular such as plasmid vectors. In addition, a suitable regulatory factor for transcription and / or translation, such as a promoter or terminator, may be linked to the protein coding region according to the type of template polynucleotide.

  According to this method, conformational control such as protein synthesis and solubilization proceeds efficiently, and a protein having an effective three-dimensional structure can be synthesized quickly. This is presumed to be due to the use of the protein synthesis medium of the present invention. Furthermore, in the synthesis process, since the folding auxiliary protein is not co-expressed with the target protein in the synthesis system, the synthesis of the target protein is It is presumed to be caused by not competing with synthesis.

  In the synthesis step of this method, it is preferable that PDI and / or thioredoxin is contained in the synthesis system. By containing these folding aid proteins related to disulfide bond formation, it is possible to efficiently produce a protein having an effective steric structure by forming or reforming an appropriate disulfide bond in the synthesized target protein. These folding assisting proteins may be co-expressed in the translation factor supplying cell, but can be added when synthesizing a protein having a disulfide bond. In particular, by containing such a disulfide bond formation-related folding auxiliary protein in the protein synthesis medium of the present invention, it is possible to easily produce a protein having a disulfide bond, which has conventionally been difficult for bacterial-derived extracts such as Escherichia coli. Can be done. Moreover, by using E. coli, a protein having a disulfide bond can be produced with high efficiency.

  The time for the protein synthesis step in this method depends on temperature and the like, but when Escherichia coli is used as a translation factor supply cell, synthesis can be performed within 1 to 24 hours. In this synthesis step, Since protein synthesis and conformation control through aggregation suppression and solubilization proceed efficiently, proteins with effective steric structures can be synthesized quickly, so the necessary amount of protein (usually for expression confirmation, function confirmation, etc.) Can be synthesized within 3 hours, and further within 1 hour. In addition, such a synthetic | combination process is implemented with various forms, such as a batch type, a continuous type, and a semi-continuous type.

  This method includes protein expression methods, protein screening methods, translation product screening methods, screening methods for chemical substances that affect transcription or translation, gene product confirmation methods, gene expression control methods, fusion The present invention can be directly applied to the protein synthesis method in the protein expression method. According to this method, since a protein having an effective three-dimensional structure can be synthesized, high-efficiency screening and the like are possible, and large-scale and high-speed screening and the like are possible.

  As described above, according to the present invention, a protein synthesis medium, a method for producing the medium, a method for producing a protein using the medium, a cell for producing the medium, and a cell-free protein containing the medium A synthesis kit is also provided. Furthermore, various screening methods and research methods including a step of synthesizing a protein using the medium will be provided.

  EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated concretely, this invention is not limited to these Examples. The gene recombination operation described below was performed according to Molecular Cloning: A Laboratory Manual (T. Maniatis, et al., Cold Spring Harbor Laboratory).

(Preparation of protein synthesis medium and cell-free protein synthesis from cell extract co-expressing folding auxiliary protein)
As the folding auxiliary protein, genes of DnaK / DnaJ operon, GrpE, and GroEL / ES operon derived from E. coli were used. Each of these three genes was linked downstream of the araB promoter, and these three fragments were incorporated into pBAD-TOPO (manufactured by Invitrogen), an E. coli plasmid vector, to construct a folding auxiliary protein expression plasmid.

  Using this plasmid vector, Escherichia coli A19 was transformed by a conventional method, and the selected Escherichia coli was cultured under the usual culture conditions with the addition of arabinose, and the cells were collected after reaching the logarithmic growth phase. After crushing the collected cells, the S30 fraction was prepared without adding DTT as a reducing agent, and this was used as a fraction containing a folding auxiliary protein, a transcription factor and a translation factor, and used as a protein synthesis medium. The S30 fraction was prepared by Zubay, G (Annu. Rev. Genet .: vol. 7, p267-287, 1973) and Jiang, X et al (FEBS Lett: vol. 154, p290-294, 2002). It went according to.

  As a template for cell-free protein synthesis, 5 to 100 μg / ml of a Streptomyces-derived β-glucosidase (hereinafter simply referred to as BGL) gene with a PCR product of a DNA added with a T7 promoter and a T7 terminator was used. 3. 56.4 mM Tris acetate buffer (pH 7.4), 1.2 mM ATP, 1 mM GTP, 1 mM CTP, 1 mM UTP, 40 mM creatine phosphate, 0.7 mM 20 amino acid mix against the previously prepared protein synthesis medium. 1% (w / w) polyethylene glycol 6000, 35 μg / ml folinic acid, 0.2 mg / ml E. coli tRNA, 36 mM ammonium acetate, 0.15 mg / ml creatine kinase, 10 mM magnesium acetate, 100 mM potassium acetate, 10 μg / ml rifampicillin, Add 7.7 μg / ml T7 RNA polymerase, 10-100 μg / ml mold PDI and 1 mM GSH (reduced glutathione) /0.1 mM GSSG (oxidized glutathione), and in vitro transcription and translation reaction at 26 ° C. for 3 hours I did it. As a control, cell-free protein synthesis was performed using a fraction prepared by culturing E. coli A19 strain, into which no plasmid vector for folding auxiliary protein expression had been introduced, as described above, except that arabinose was not added, as a protein synthesis medium. went. As the mold PDI, a high heat-resistant PDI obtained from a culture of microorganisms belonging to the genus Humicola described in JP-A-6-38752 was used.

  Each 15 μL of the resultant synthesis reaction product is added to a 50 mM sodium phosphate buffer (pH 6.5) containing 2 mM pNPG (p-nitrile-β-D-glucopyranoside), which is a chromogenic substrate, and decomposed to produce p -The increase in the absorbance (405 nm) of nitrophenyl was measured, and this was defined as BGL activity. The result is shown in FIG.

  As shown in FIG. 1, when the protein synthesis medium of this example was used, about 11 times BGL activity was recognized as compared with the control synthesis medium. Since BGL is a protein having a disulfide bond and forming a dimer, BGL is correctly folded by the protein synthesis medium of this example, and an appropriate disulfide bond is formed by the addition of PDI. It was thought that it was synthesized as a protein with a three-dimensional structure.

(Effect in protein synthesis medium with additional folding auxiliary protein)
1 μMDnaK, 0.4 μM DnaJ, 0.4 μM GrpE, 1.25 μM GroEL and 1.25 μM GroEL obtained as separately purified products were added to the control protein synthesis medium prepared in Example 1 in various modes. A protein synthesis reaction was carried out in the same manner as in Example 1. BGL activity in the synthesized product was measured. The results are shown in FIG. In FIG. 2, the presence or absence of introduction of various folding auxiliary proteins is indicated by + and −, respectively.

  As shown in FIG. 2, even when DnaK, DnaJ and GrpE were added, the BGL activity did not increase so much, but by adding only GroEL and GroES, it was about 5 times that of the control. Increased activity was observed. In addition, when all folding auxiliary proteins were added, slightly higher BGL activity was observed than when GroEL and GroES were added. From the above, it was found that GroEL and GroES mainly support BGL folding.

(Comparison with protein synthesis media obtained by inducing the expression of folding auxiliary proteins by heat shock)
E. coli A19 strain used as a control in Example 1 was used and cultured under the same culture conditions except that arabinose was not added. After reaching the logarithmic growth phase, a heat shock was applied at 42 ° C. for 30 minutes, and then the cells were recovered. Then, a protein synthesis medium was prepared by the same method, cell-free protein synthesis was performed using the prepared fraction as a protein synthesis medium, and BGL activity was measured. The results are shown in FIG. FIG. 3 also shows the BGL activity of Example 1 and the control.

  As shown in FIG. 3, in the protein synthesis system using the protein synthesis medium in which the folding auxiliary protein was induced by heat shock, about twice as much BGL activity as that in the control of Example 1 was observed. 1/6 or less compared to 1 protein synthesis medium.

  Furthermore, cell-free protein synthesis was performed in the same manner as in Example 1 except that 5 μM GroEL and 5 μM GroES were added to each protein synthesis medium based on Example 1, control, and heat shock, and BGL activity was measured. Is also shown in FIG. In FIG. 3, the protein synthesis medium to which GroEL and GroES are added is shown as “+ GroE”.

  As shown in FIG. 3, when GroEL and GroES, which were thought to effectively support BGL folding, were added at a high concentration (5 μM), the protein synthesis medium of Example 1 did not increase BGL activity. BGL activity increased in protein synthesis media by control and heat shock. Therefore, according to the protein synthesis medium of Example 1, there are sufficient amounts of folding auxiliary proteins such as GroEL and GroES, and these cooperate with transcription factors and translation factors to solubilize and correct three-dimensional proteins. It was thought that structure formation was promoted. Furthermore, it was considered that an appropriate disulfide bond was folded, and as a result, a protein with an appropriate disulfide bond was synthesized by PDI.

It is a graph which shows the measurement result of BGL activity in Example 1, and is a figure which shows the folding capability of the protein synthesis medium of this invention. It is a graph which shows the measurement result of BGL activity in Example 2, and is a figure which shows the influence which addition of each folding auxiliary protein exerts on folding ability. It is a graph which shows the measurement result of BGL activity in Example 3, and is a figure which shows the folding capability of each protein synthesis medium by control, heat shock (42 degreeC, 30 minutes), and this invention.

Claims (14)

A medium for a cell-free protein synthesis system,
Cell extraction containing the folding auxiliary protein, translation factor, and transcription factor in the cell obtained from a cell in which the expression ability of one or more folding auxiliary proteins is activated or imparted by genetic recombination A medium containing fractions .   The medium according to claim 1, wherein the folding assisting protein is selected from the Hsp70 family, the Hsp60 family, and a protein family related to disulfide bond formation.   The medium according to claim 1 or 2, wherein the folding auxiliary protein is selected from DnaK, DnaJ, GrpE, GroES, and GroEL. The medium according to any one of claims 1 to 3 , wherein the target protein to be synthesized is a multimeric protein or a protein having a disulfide bond. The medium according to any one of claims 1 to 4 , wherein the cell is Escherichia coli or yeast. A protein production method comprising:
Comprising the step of synthesizing a protein using medium for cell-free protein synthesis system according to any one of claims 1 to 5, the method. The method according to claim 6 , wherein in the synthesis step, the medium contains protein disulfide isomerase and / or thioredoxin. The method according to claim 6 or 7 , wherein the synthesis step is carried out within 3 hours. A method for producing a medium for a cell-free protein synthesis system, comprising:
Culturing cells in which the expression ability of one or more folding auxiliary proteins is activated or imparted by genetic recombination;
Collecting a fraction containing at least a translation factor, a transcription factor, and the folding auxiliary protein in the cultured cells;
A method comprising: The cell is a transformant in which the folding auxiliary protein is introduced into the cell with a polynucleotide encoding a folding auxiliary protein selected from the Hsp70 family, the Hsp60 family, and a protein family related to disulfide bond formation. Item 10. The method according to Item 9 . The method according to claim 9 or 10 , wherein the collecting step is carried out without causing a reducing agent to act on the fraction. A cell-free protein synthesis kit,
A kit comprising a medium for a cell-free protein synthesis system according to any one of claims 1 to 5 . A cell for producing a medium for a cell-free protein synthesis system according to any one of claims 1 to 5 , which is a cell in which the expression ability of a folding auxiliary protein is activated or imparted by genetic recombination. A protein screening method comprising:
Synthesizing a target protein using a medium for a cell-free protein synthesis system according to any one of claims 1 to 5 ,
Confirming whether or not the synthesized target protein has a function according to the purpose to be screened;
A method comprising:

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