WO2014157492A1 - 耐熱性セロビオハイドロラーゼ - Google Patents
耐熱性セロビオハイドロラーゼ Download PDFInfo
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- WO2014157492A1 WO2014157492A1 PCT/JP2014/058798 JP2014058798W WO2014157492A1 WO 2014157492 A1 WO2014157492 A1 WO 2014157492A1 JP 2014058798 W JP2014058798 W JP 2014058798W WO 2014157492 A1 WO2014157492 A1 WO 2014157492A1
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12N—MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
- C12N9/00—Enzymes; Proenzymes; Compositions thereof; Processes for preparing, activating, inhibiting, separating or purifying enzymes
- C12N9/14—Hydrolases (3)
- C12N9/24—Hydrolases (3) acting on glycosyl compounds (3.2)
- C12N9/2402—Hydrolases (3) acting on glycosyl compounds (3.2) hydrolysing O- and S- glycosyl compounds (3.2.1)
- C12N9/2405—Glucanases
- C12N9/2434—Glucanases acting on beta-1,4-glucosidic bonds
- C12N9/2437—Cellulases (3.2.1.4; 3.2.1.74; 3.2.1.91; 3.2.1.150)
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12P—FERMENTATION OR ENZYME-USING PROCESSES TO SYNTHESISE A DESIRED CHEMICAL COMPOUND OR COMPOSITION OR TO SEPARATE OPTICAL ISOMERS FROM A RACEMIC MIXTURE
- C12P19/00—Preparation of compounds containing saccharide radicals
- C12P19/02—Monosaccharides
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- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12P—FERMENTATION OR ENZYME-USING PROCESSES TO SYNTHESISE A DESIRED CHEMICAL COMPOUND OR COMPOSITION OR TO SEPARATE OPTICAL ISOMERS FROM A RACEMIC MIXTURE
- C12P19/00—Preparation of compounds containing saccharide radicals
- C12P19/14—Preparation of compounds containing saccharide radicals produced by the action of a carbohydrase (EC 3.2.x), e.g. by alpha-amylase, e.g. by cellulase, hemicellulase
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- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12Y—ENZYMES
- C12Y302/00—Hydrolases acting on glycosyl compounds, i.e. glycosylases (3.2)
- C12Y302/01—Glycosidases, i.e. enzymes hydrolysing O- and S-glycosyl compounds (3.2.1)
- C12Y302/01091—Cellulose 1,4-beta-cellobiosidase (3.2.1.91)
Definitions
- the present invention relates to the thermostability of cellobiohydrolase enzymes.
- Cellobiohydrolase is one of glycoside hydrolases involved in the process of hydrolyzing lignocellulose such as cellulose and hemicellulose to produce monosaccharides. More specifically, a novel thermostable cellobiohydrolase, a polynucleotide encoding the thermostable cellobiohydrolase, an expression vector for expressing the thermostable cellobiohydrolase, and a trait in which the expression vector is incorporated
- the present invention relates to a converter and a method for producing a cellulose degradation product using the thermostable cellobiohydrolase.
- biomass or lignocellulose
- the main components of biomass dry weight are polysaccharides such as cellulose and hemicellulose and lignin.
- polysaccharides are hydrolyzed into monosaccharides such as glucose and xylose by glycoside hydrolase, collectively called cellulase enzymes, and then used as biofuels or chemical raw materials.
- Lignocellulose having a complex structure is difficult to decompose and is difficult to be decomposed and saccharified by a single enzyme.
- the glycoside hydrolase endoglucanase (cellulase or endo-1,4- ⁇ -D-glucanase, EC 3.2.1.4), exo-type cellobiohydro
- Three types of enzymes are required: a lase (1,4- ⁇ -cellobiosidase or cellobiohydrolase, EC 3.2.1.91) and ⁇ -glucosidase (EC 3.2.1.21).
- saccharification treatment with a high solid load (30 to 60% solid loading) has been attempted for the purpose of high-efficiency conversion of ethanol.
- Such saccharification with a high solid load has a high viscosity of the biomass saccharified liquid and the enzyme reaction is difficult to proceed, but the viscosity of the biomass saccharified liquid decreases by performing at a high temperature, resulting in shortening of the saccharification reaction time and reduction of the amount of enzyme. Is expected.
- the chemical reaction increases by 2 to 3 times as the temperature increases by 10 ° C. according to the Van't Hoff-Arrhenius law.
- thermostable cellulase enzyme when lignocellulose saccharification treatment is performed at a higher temperature than before using a thermostable cellulase enzyme, a high enzyme reaction rate will be obtained according to this rule of thumb. For these reasons, it is considered that by performing lignocellulose saccharification treatment at a high temperature using a thermostable enzyme, the amount of enzyme and the saccharification time are greatly reduced, and the enzyme cost can be greatly reduced.
- thermophilic filamentous fungi which are eukaryotes, have a lower survival limit of about 55 ° C. compared to prokaryotic thermophilic bacteria and hyperthermophilic archaea. For this reason, the heat resistance of glycoside hydrolase expressed and secreted by thermophilic filamentous fungi is generally not so high.
- the most thermophilic fungus-derived CBH (cellobiohydrolase) reported so far is the thermophilic fungus Chaetomium thermophilum cellobiohydrolase CBHI, CBHII, which has optimum temperatures of 75 ° C and 70 ° C, respectively.
- Thermoascus aurantiacus cellobiohydrolase CBHI has an optimum temperature of 65 ° C. (for example, see Non-Patent Document 2).
- There is also a method for improving the heat resistance by substituting one or a plurality of amino acids in cellobiohydrolase see, for example, Patent Document 1 or 2), but the mutant cellobiohydroly obtained in this way. The heat resistance of ase is still insufficient.
- thermophilic bacteria that grow at 55 ° C. or higher and hyperthermophilic bacteria that grow at 80 ° C. or higher are separated and cultured from extreme environments such as hot springs, hydrothermal vents, oil fields, and mines.
- Most of the thermostable glycoside hydrolases derived from these thermophilic bacteria and hyperthermophilic archaea are enzymes having endoglucanase activity, xylanase activity, xylosidase activity, or glucosidase activity.
- thermophilic anaerobic bacterium Clostridium thermocellum presents an enzyme complex cellulosome having high lignocellulose hydrolysis activity outside the microbial cell.
- thermophilic actinomycetes Thermobifida fusca E3 belonging to the GH6 family (see, for example, Non-Patent Document 6) and Cel48A belonging to the GH48 family (see, for example, Non-Patent Document 7).
- E3 belonging to the GH6 family
- Cel48A belonging to the GH48 family
- These cellobiohydrolases are relatively thermostable, the temperature range showing 50% activity at the maximum is 40-60 ° C. and has stable activity at 55 ° C. for at least 16 hours.
- these two types of cellobiohydrolase have insufficient activity at 70 ° C.
- the upper limit of the saccharification treatment temperature is 60 to 65 ° C.
- the enzyme exhibits endoglucanase-like substrate specificity and exhibits degradation activity only for amorphous cellulose and carboxymethylcellulose (CMC).
- CMC carboxymethylcellulose
- the present invention relates to a novel thermostable cellobiohydrolase exhibiting cellobiohydrolase activity at least at 75 ° C., a polynucleotide encoding the thermostable cellobiohydrolase, and expression for expressing the thermostable cellobiohydrolase. It aims at providing the manufacturing method of the degradation product of the cellulose using the vector, the transformant in which the said expression vector was integrated, and the said thermostable cellobiohydrolase.
- the present inventors directly extracted DNA from hot spring high-temperature soil, and performed a large-scale metagenomic sequence of a difficult-to-cultivate microflora, thereby producing a thermostable cellobiohydrolase having a novel amino acid sequence.
- the acquisition was successful and the present invention was completed.
- Thermostable cellobiohydrolase, polynucleotide, expression vector, transformant, method for producing thermostable cellobiohydrolase, cellulase mixture, method for producing cellulose degradation product, method for producing polynucleotide, and primer of the present invention include: For example, it has the following aspects [1] to [17].
- the first aspect of the present invention is (A) a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 1, (B) It consists of an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- a polypeptide having ase activity (C) a polypeptide comprising an amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 1 and having cellobiohydrolase activity under conditions of at least 75 ° C. and pH 5.5, (D) a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 3, (E) an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 3 are deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C.
- a polypeptide having ase activity (F) a polypeptide comprising an amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 3 and having cellobiohydrolase activity under conditions of at least 75 ° C. and pH 5.5, (G) a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 5, (H) an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 5 are deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C.
- a polypeptide having ase activity (I) a polypeptide comprising an amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 5 and having cellobiohydrolase activity under conditions of at least 75 ° C. and pH 5.5, (J) a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 7, (K) It consists of an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 7 are deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- a polypeptide having a ase activity or (L) an amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 7, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5
- a polypeptide having ase activity It is a thermostable cellobiohydrolase having a cellobiohydrolase catalytic region.
- the heat-resistant cellobiohydrolase of [1] preferably further has a cellulose-binding module.
- a second aspect of the present invention is (A) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 1, (B) consisting of an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5 A base sequence encoding a polypeptide having ase activity, (C) Coding a polypeptide comprising an amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 1 and having cellobiohydrolase activity under conditions of at least 75 ° C.
- Base sequence (D) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 3, (E) an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 3 are deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5 A base sequence encoding a polypeptide having ase activity, (F) coding for a polypeptide comprising an amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 3 and having cellobiohydrolase activity under conditions of at least 75 ° C.
- Base sequence (G) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 5, (H) an amino acid sequence in which one or several amino acids of the amino acid sequence represented by SEQ ID NO: 5 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5 A base sequence encoding a polypeptide having ase activity, (I) A polypeptide comprising the amino acid sequence having 80% or more sequence identity with the amino acid sequence represented by SEQ ID NO: 5 and having cellobiohydrolase activity under the conditions of at least 75 ° C.
- Base sequence, (M) has 80% or more sequence identity with the base sequence represented by SEQ ID NO: 2, 4, 6, or 8 and has cellobiohydrolase activity at least under conditions of 75 ° C. and pH 5.5.
- a base sequence encoding a polypeptide, or (n) a base sequence of a polynucleotide that hybridizes under stringent conditions with a polynucleotide comprising the base sequence represented by SEQ ID NO: 2, 4, 6, or 8.
- a polynucleotide having a region encoding a cellobiohydrolase catalytic region is 80% or more sequence identity with the base sequence represented by SEQ ID NO: 2, 4, 6, or 8 and has cellobiohydrolase activity at least under conditions of 75 ° C. and pH 5.5.
- the polynucleotide of [3] preferably further has a region encoding a cellulose binding module.
- the polynucleotide of [3] or [4] is incorporated, and cellobiohydrolase activity is exhibited in a host cell under conditions of at least 75 ° C. and pH 5.5.
- a fourth aspect of the present invention is a transformant into which the expression vector of [5] has been introduced.
- the transformant of [6] is preferably a eukaryotic microorganism.
- the transformant of [6] is preferably a plant.
- a fifth aspect of the present invention is a method for producing a thermostable cellobiohydrolase, wherein the thermostable cellobiohydrolase is produced in the transformant according to any one of [6] to [8]. .
- the sixth aspect of the present invention is the production of the thermostable cellobiohydrolase of [1], the thermostable cellobiohydrolase of [2], or the thermostable cellobiohydrolase of [9].
- a cellulase mixture comprising a thermostable cellobiohydrolase produced by the method and at least one other cellulase.
- the other cellulase is preferably at least one selected from the group consisting of hemicellulase and endoglucanase.
- the material containing cellulose comprises the heat-resistant cellobiohydrolase of [1], the heat-resistant cellobiohydrolase of [2], and [6] to [8]. Production of a cellulose degradation product by contact with any one of the above transformants or the thermostable cellobiohydrolase produced by the method for producing a thermostable cellobiohydrolase of [9] above Is the method.
- the eighth aspect of the present invention is the nucleotide sequence represented by SEQ ID NO: 12 or the nucleotide sequence represented by SEQ ID NO: 12, using a reverse transcription product of DNA derived from organisms or RNA derived from organisms as a template.
- a heat-stable cellobiohydrolase that performs PCR using a reverse primer consisting of a base sequence to which a single base has been added, and obtains a polynucleotide containing a base sequence encoding a heat-stable cellobiohydrolase as an amplification product Is a method for producing a polynucleotide encoding.
- a ninth aspect of the present invention relates to a nucleotide sequence represented by SEQ ID NO: 12, or a nucleotide sequence in which one or several bases are added to the 5 ′ end of the nucleotide sequence represented by SEQ ID NO: 12. Is a primer.
- a nucleotide sequence represented by SEQ ID NO: 13 or a nucleotide sequence in which one or several bases are added to the 5 ′ end of the nucleotide sequence represented by SEQ ID NO: 13. Is a primer.
- the present invention has the following aspects.
- A a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 1
- B It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- a polypeptide having ase activity (C) a polynuclear acid comprising the amino acid sequence having the sequence identity of 80% or more and less than 100% with the amino acid sequence represented by SEQ ID NO: 1 and having cellobiohydrolase activity under the conditions of at least 75 ° C.
- polypeptide having ase activity (G) a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 5, (H) an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 5 are deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5 A polypeptide having ase activity, (I) a polynuclear acid comprising the amino acid sequence having the sequence identity of 80% or more and less than 100% with the amino acid sequence represented by SEQ ID NO: 5 and having cellobiohydrolase activity under the conditions of at least 75 ° C.
- (J) a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 7, (K) It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 7 are deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- thermostable cellobiohydrolase having a cellobiohydrolase catalytic region
- thermostable cellobiohydrolase according to [1], further comprising a cellulose binding module, [3] (a) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 1, (B) consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C.
- a base sequence encoding a polypeptide having ase activity (C) a polynuclear acid comprising the amino acid sequence represented by SEQ ID NO: 1 having a sequence identity of 80% or more and less than 100% and having cellobiohydrolase activity under the conditions of at least 75 ° C and pH 5.5 A base sequence encoding a peptide, (D) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 3, (E) consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 3 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C.
- a base sequence encoding a polypeptide having ase activity (F) a polymorph which comprises the amino acid sequence having the sequence identity of 80% or more and less than 100% with the amino acid sequence represented by SEQ ID NO: 3 and has cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5
- a base sequence encoding a peptide (G) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 5, (H) It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 5 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- a base sequence encoding a polypeptide having ase activity (I) a polymorph having a cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5, comprising the amino acid sequence having the sequence identity of 80% or more and less than 100% with the amino acid sequence represented by SEQ ID NO: 5
- a base sequence encoding a peptide (J) a base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 7, (K) consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 7 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C.
- a base sequence encoding a polypeptide having ase activity (L) a polynuclear acid comprising the amino acid sequence represented by SEQ ID NO: 7 and having an identity of 80% or more and less than 100% and having cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5 A base sequence encoding a peptide, (M) Cellobiohydrolase having a sequence identity of 80% or more and less than 100% with the base sequence represented by SEQ ID NO: 2, 4, 6, or 8 and at least at 75 ° C.
- a base sequence encoding a polypeptide having activity or (n) a base sequence of a polynucleotide that hybridizes under stringent conditions with a polynucleotide comprising the base sequence represented by SEQ ID NO: 2, 4, 6, or 8. And a nucleotide sequence encoding a polypeptide having cellobiohydrolase activity under conditions of at least 75 ° C.
- a polynucleotide having a region encoding a cellobiohydrolase catalytic region [4] The polynucleotide according to [3], further comprising a region encoding a cellulose-binding module, [5] The polynucleotide according to [3] or [4] is incorporated, An expression vector capable of expressing a polypeptide having cellobiohydrolase activity under the conditions of at least 75 ° C.
- thermostable cellobiohydrolase which produces a thermostable cellobiohydrolase in the transformant according to any one of [6] to [9], [11] A heat-resistant cellobiohydrolase according to [1], a heat-resistant cellobiohydrolase according to [2], or a heat-resistant produced by the method for producing a thermostable cellobiohydrolase according to [10] A cellulase mixture comprising sex cellobiohydrolase and at least one other cellulase, [12] The cellulase mixture according to [11], wherein the other cellulase is one or more cellulases selected from the group consisting of hemicellulase and endoglucanase, [13] The material containing cellulose is the thermostable cellobiohydrolase according to [1], the thermostable cellobiohydrolase according to [2], or any one
- a method for producing a cellulose degradation product wherein a cellulose degradation product is produced by contacting the transformant or the thermostable cellobiohydrolase produced by the method for producing a thermostable cellobiohydrolase according to [10], [14] The method for producing a cellulose degradation product according to [13], wherein the material containing cellulose is further contacted with at least one other cellulase.
- thermostable cellobiohydrolase according to the present invention has cellobiohydrolase activity at least at 75 ° C. and pH 5.5. For this reason, the thermostable cellobiohydrolase is suitable for saccharification treatment of cellulose under high temperature conditions.
- the polynucleotide according to the present invention, the expression vector incorporating the polynucleotide, and the transformant into which the expression vector is introduced are preferably used for the production of the thermostable cellobiohydrolase according to the present invention.
- Example 1 a rooted molecule having an amino acid sequence deduced from four open reading frames (AR19G-166, AR19G-12 (and OJ1-2), OJ1-1) belonging to the GH6 family obtained by metagenomic analysis It is a phylogenetic tree. Since the amino acid sequence of OJ1-2 is 100% homologous (identical) to AR19G-12, OJ1-2 is presumed to be the same gene as AR19G-12 and a partial sequence of AR19G-12.
- FIG. 2 is an amino acid sequence deduced from an open reading frame OJ1-1 and an amino acid sequence alignment diagram of a cellulose-binding module CBM3 of a thermophilic aerobic bacterium Caldibacillus cellulovorans.
- Polypeptides consisting of amino acid sequences deduced from open reading frames (AR19G-166, AR19G-12, OJ1-1), and the Chloroflexus mesophilic aerobic bacterium Herpetosiphon aurantiacus DSM 785 having the highest sequence identity with these amino acid sequences
- FIG. 2 is a schematic diagram of amino acids of a polypeptide consisting of an amino acid sequence deduced from the open reading frame OJ1-1, and a cellulose binding module CBM3 of a thermophilic aerobic bacterium, Caldibacillus cellulovorans.
- FIG. 1 is a schematic diagram of amino acids of a polypeptide consisting of an amino acid sequence deduced from the open reading frame OJ1-1, and a cellulose binding module CBM3 of a thermophilic aerobic bacterium, Caldibacillus cellulovorans.
- Example 2 shows the results of SDS-PAGE analysis (A) and Western blot analysis (B) of AR19G-166-RA protein and AR19G-166-QV protein expressed in E. coli in Example 1.
- A SDS-PAGE analysis
- B Western blot analysis
- E._coli by the high performance liquid chromatography (HPLC).
- Example 1 it is the figure which showed the analysis result of the PSA hydrolysis reaction product of the family 6 cellobiohydrolase TrCBHII of filamentous fungus Trichoderma reesei by the high performance liquid chromatography (HPLC).
- Example 1 it is the figure which showed the result of having measured the PSA hydrolysis activity in each temperature of the AR19G-166-RA protein expressed by E. coli. In Example 1, it is the figure which showed the result of having measured the PSA hydrolysis activity in each temperature of the AR19G-166-QV protein expressed by Escherichia coli. In Example 1, it is the figure which showed the result of having measured the PSA hydrolysis activity in each pH of AR19G-166-RA protein expressed by colon_bacillus
- Example 1 it is the figure which showed the result of having measured the influence of the preincubation time of AR19G-166-RA protein expressed by colon_bacillus
- Example 2 the medium supernatant of Aspergillus oryzae transformants introduced with the AR19G-166-RW gene and Aspergillus transformant introduced with the AR19G-166-QW gene, the AR19G-166-RA prepared in Example 1, and FIG. 6 shows the results of Western blot analysis of AR19G-166-QV recombinant E. coli disrupted supernatant.
- PSA hydrolysis activity U / mg
- FIG. 1 the medium supernatant of Aspergillus oryzae transformants introduced with the AR19G-166-RW gene and Aspergillus transformant introduced with the AR19G-166-QW gene, the AR19G-166-RA prepared in Example 1
- FIG. 6 shows the results of Western blot analysis of AR
- FIG. 3 is a graph showing the results of determining the PSA hydrolysis activity (relative value (%)) of protein and AR19G-166-QW protein.
- FIG. 3 is a graph showing the results of determining the PSA hydrolysis activity (relative value (%)) of protein and AR19G-166-QW protein.
- Example 3 it is the schematic diagram of cassette vector pNtaGL and pNtaGLPL for tobacco chloroplast transformation used for tobacco chloroplast transformation preparation.
- Example 3 it is a schematic diagram of the cassette pPXT and pPXTPPL for tobacco chloroplast transformation used for preparation of tobacco chloroplast transformants.
- Example 3 it is a schematic diagram of the expression vectors pNtaGL-QV and pNtaGLPL-RA incorporating the expression cassette for tobacco chloroplast transformation used for the production of tobacco chloroplast transformants.
- Example 3 Southern hybridization results of two lines of chloroplast-transformed tobacco (QV-2, QV-17) and wild-type tobacco (WT (SR-1)) obtained by introduction of pNtaGL-QV FIG.
- Example 3 three lines of chloroplast-transformed tobacco (RA-6-2-1, RA-6-2-2, RA-6-2-3) obtained by introduction of pNtaGLPL-RA and wild It is the figure which showed the result of Southern hybridization of type tobacco (WT (SR-1)). In Example 3, it is the figure which showed the result of the Southern hybridization of the chloroplast transformation tobacco obtained by introduction
- Example 3 the flowering time, a photograph of AR19G-166-RA chloroplast transformed tobacco plants obtained by the introduction of (T 1 generation).
- Western of the soluble protein extract extracted from the chloroplast-transformed tobacco plant obtained by introducing AR19G-166-QV and the chloroplast-transformed tobacco plant obtained by introducing pNtaGL It is the figure which showed the blot analysis result.
- Example 3 SDS of the soluble protein extract extracted from the chloroplast-transformed tobacco plant obtained by introducing AR19G-166-RA and the chloroplast-transformed tobacco plant obtained by introducing pNtaGLPL -A figure showing the results of PAGE analysis.
- the soluble protein extract was extracted from the chloroplast-transformed tobacco plant obtained by introducing AR19G-166-RA and the chloroplast-transformed tobacco plant obtained by introducing pNtaGLPL. It is the figure which showed the blot analysis result.
- FIG. 6 is a graph showing the PSA hydrolysis activity of AR19G-166-QV protein expressed in tobacco chloroplasts in Example 3 at each temperature in terms of reducing sugar amount (mM).
- Example 3 is a graph showing the PSA hydrolysis activity of the AR19G-166-RA protein expressed in tobacco chloroplasts in Example 3 at each temperature in terms of reducing sugar amount (mM).
- Example 4 it is the figure which showed the Western blot analysis result of AR19G-166-RA protein and AR19G-166-QV protein which were expressed in Arabidopsis thaliana.
- Example 4 it is the figure which showed the temperature dependence of PSA hydrolysis activity (mM reducing sugar / 20min) of AR19G-166-RA protein and AR19G-166-QV protein expressed in Arabidopsis thaliana.
- Example 5 it is the figure which showed the SDS-PAGE analysis result of the cell-free extract extracted from the recombinant actinomycetes obtained by introduction
- Example 6 it is the figure which showed the SDS-PAGE analysis result of the enzyme protein obtained by expressing CBM addition AR19G-166-RA protein in colon_bacillus
- Example 6 it is the figure which showed the Western blot analysis result of the enzyme protein obtained by expressing CBM addition AR19G-166-RA protein in colon_bacillus
- FIG. 6 shows the temperature dependence of PSA hydrolysis activity (U / mg) of CBM-added AR19G-166-RA protein expressed in E. coli in Example 6 at each temperature. It is the figure which showed the temperature dependence of Avicel degradation activity (U / mg) of CBM addition AR19G-166-RA protein expressed in colon_bacillus
- thermostable cellobiohydrolase Many microorganisms including filamentous fungi, bacteria, and archaea are difficult to cultivate, and 99% of the bacteria that inhabit microbial environments such as soil are said to be unknown. In particular, it is extremely difficult to cultivate microorganisms that inhabit high-temperature environments, and it is considered that only 0.1% or less of microorganisms that inhabit the soil are isolated and cultured with current microorganism culture technology. . This difficulty in culturing high-temperature soil microorganisms is one of the reasons for the development of thermostable cellobiohydrolase.
- genomic DNA (metagenomic DNA) of a microbial population from hot hot spring soil collected from five locations in Japan, performed a shotgun sequence and annotation of metagenomic DNA, 44 open reading frames (ORF) having amino acid sequences similar to known cellobiohydrolase enzymes were obtained. Primers were designed based on the base sequence information of these ORFs, and gene candidates were cloned from high temperature hot spring soil metagenomic DNA by PCR.
- thermostable cellobiohydrolase having PSA decomposition activity was obtained from one ORF.
- thermostable cellobiohydrolases in which two amino acids were substituted were obtained by PCR cloning.
- the amino acid at position 299 is arginine (R) and the amino acid at position 351 is alanine (A) is AR19G-166-RA, and the amino acid at position 299 is glutamine (Q).
- AR19G-166-QV was defined as the amino acid at position 351 being valine (V).
- the nucleotide sequence of AR19G-166-RA is shown in SEQ ID NO: 2
- amino acid sequence of AR19G-166-RA is shown in SEQ ID NO: 1, respectively.
- AR19G-166-QV The base sequence of AR19G-166-QV is shown in SEQ ID NO: 4, and the amino acid sequence of AR19G-166-QV is shown in SEQ ID NO: 3, respectively. Since AR19G-166-RA and AR19G-166-QV obtained by PCR cloning did not have an initiating methionine, these are cellobiohydrolase gene cellos that the microorganisms contained in the high temperature hot spring soil had. It was inferred to be a partial gene only in the biohydrolase catalytic region.
- AR19G-166-RA and AR19G-166-QV show high hydrolytic activity for PSA, and are composed of ⁇ -1,3 bond and ⁇ -1,4 bond glucan. In addition, it showed degradation activity against Avicel, a crystalline cellulose, although it was weak. On the other hand, CMC and Laminarin composed of ⁇ -1,3 bond and ⁇ -1,6 bond glucan showed almost no degradation activity.
- HPLC high performance liquid chromatography
- the amino acid sequence having the highest sequence identity was found to be a known chloroflexus mesophilic aerobic bacterium. It is a glucoside hydrolase (SEQ ID NO: 15) belonging to the GH6 family of Herpetosiphon aurantiacus DSM 785, and its sequence identity was only 66%.
- AR19G-166-RA and AR19G-166-QV are part of the GH6 family due to substrate specificity, HPLC analysis of PSA hydrolysis reaction products, and sequence identity (homology) of the amino acid sequence with known cellobiohydrolase. It became clear to be a novel cellobiohydrolase to which it belongs.
- Both AR19G-166-RA and AR19G-166-QV have cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5. Actually, as will be described later in Example 1 ⁇ 13>, AR19G-166-RA and AR19G-166-QV both exhibit cellobiohydrolase activity within a wide temperature range of 30 to 100 ° C. However, the optimum temperature range for the cellobiohydrolase activity was different. The cellobiohydrolase activity of AR19G-166-RA expressed using E. coli as a host increases as the temperature increases within the range of 30 to 80 ° C., and increases as the temperature increases within the range of 80 to 100 ° C. Cellobiohydrolase activity tended to decrease.
- the cellobiohydrolase activity of AR19G-166-QV increases as the temperature increases within the range of 30 to 70 ° C, peaks at around 70 ° C, and increases within the range of 70 to 100 ° C. It showed a tendency to decrease as it increased.
- cellobiohydrolase activity means at least one compound selected from the group consisting of glucan composed of ⁇ -1,3 bond and ⁇ -1,4 bond, and crystalline cellulose, and It means the activity of producing cellobiose by using phosphoric acid swollen Avicel as a substrate and hydrolyzing the substrate from the non-reducing end side.
- a polypeptide having cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5 means that the solution containing the polypeptide has a pH of 75 ° C. when the pH is 5.5. It means having the highest cellobiohydrolase activity.
- the “thermostable cellobiohydrolase” is preferably an enzyme having the cellobiohydrolase activity at 55 to 80 ° C. and pH 3.5 to 7.0, preferably 70 to 100 ° C. and pH 4.
- An enzyme having cellobiohydrolase activity at 0 to 6.0 is more preferable.
- AR19G-166-RW in which the amino acid residue at position 351 of AR19G-166-RA is replaced with tryptophan (W), and AR19G-166 in which the amino acid residue at position 351 in AR19G-166-QV is replaced with tryptophan (W) -QW like AR19G-166-RA and AR19G-166-QV, also has cellobiohydrolase activity under conditions of at least 75 ° C. and pH 5.5.
- the amino acid sequence of AR19G-166-RW is shown in SEQ ID NO: 5, the nucleotide sequence encoding it is shown in SEQ ID NO: 6, the amino acid sequence of AR19G-166-QW is shown in SEQ ID NO: 7, and the nucleotide sequence encoding it is sequenced. The number 8 is shown respectively.
- the cellobiohydrolase activity of AR19G-166-RW and AR19G-166-QW expressed using Aspergillus oryzae as a host increases with increasing temperature within the range of 30 to 100 ° C., and the highest cellobio at 100 ° C. Showed hydrolase activity.
- a protein having some physiological activity can be deleted, substituted or added with one or a plurality of amino acids without impairing the physiological activity.
- AR19G-166-RA, AR19G-166-QV, AR19G-166-RW, or AR19G-166-QW can also contain one or more amino acids without losing cellobiohydrolase activity. It can be deleted, substituted or added.
- thermostable cellobiohydrolase which is the first aspect of the present invention is a thermostable cellobiohydrolase having a cellobiohydrolase catalytic region consisting of any of the following (A) to (L).
- a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 1.
- B It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- a polypeptide having ase activity is a thermostable cellobiohydrolase having a cellobiohydrolase catalytic region consisting of any of the following (A) to (L).
- a polypeptide comprising the amino acid sequence represented by SEQ ID NO: 1.
- B It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under
- (C) a polynuclear acid comprising the amino acid sequence having the sequence identity of 80% or more and less than 100% with the amino acid sequence represented by SEQ ID NO: 1 and having cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5 peptide.
- (D) A polypeptide comprising the amino acid sequence represented by SEQ ID NO: 3.
- (E) It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 3 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5 A polypeptide having ase activity.
- a polypeptide having ase activity is provided.
- (L) a polynuclear acid comprising the amino acid sequence represented by SEQ ID NO: 7 and having an identity of 80% or more and less than 100% and having cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5 peptide.
- “deletion of amino acids in a polypeptide” means that a part of amino acids constituting the polypeptide is lost (removed).
- “an amino acid is substituted in a polypeptide” means that an amino acid constituting the polypeptide is changed to another amino acid.
- “an amino acid is added in a polypeptide” means that a new amino acid is inserted into the polypeptide.
- amino acids that are deleted, substituted, or added to the amino acid sequence represented by SEQ ID NO: 1, 3, 5, or 7 The number of is preferably 1 to 20, more preferably 1 to 10, and still more preferably 1 to 5.
- the position of the amino acid to be deleted, substituted or added is not particularly limited, but the amino acid at position 299 is preferably arginine.
- polypeptides (C), (F), (I), and (L) the sequence identity with the amino acid sequence represented by SEQ ID NO: 1, 3, 5, or 7 is 80% or more and 100% although it will not specifically limit if it is less than 85%, it is preferable that it is 85% or more and less than 100%, It is more preferable that it is 90% or more, It is more preferable that it is 95% or more and less than 100%.
- sequence identity between amino acid sequences is the alignment obtained by juxtaposing two amino acid sequences side by side with a gap in the portion corresponding to insertion and deletion so that the corresponding amino acids most closely match. It is determined as the ratio of matched amino acids to the entire amino acid sequence excluding the gap in the middle.
- sequence identity between amino acid sequences can be determined using various homology search software known in the art.
- sequence identity value of the amino acid sequence in the present invention is obtained by calculation based on the alignment obtained by the known homology search software BLASTP.
- polypeptides (B), (C), (E), (F), (H), (I), (K), and (L) may be artificially designed. It may be a homologue such as AR19G-166-QV or a partial protein thereof.
- Each of the polypeptides (A) to (L) may be chemically synthesized on the basis of the amino acid sequence, and can be synthesized by a protein expression system using the polynucleotide according to the second aspect of the present invention described later. May be produced.
- the polypeptides (B), (C), (E), (F), (H), (I), (K), and (L) are represented by SEQ ID NOs: 1, 3, 5, Alternatively, based on the polypeptide consisting of the amino acid sequence represented by 7, it can be artificially synthesized using a gene recombination technique for introducing an amino acid mutation.
- the polypeptides (A) to (L) have cellobiohydrolase activity under the conditions of at least 75 ° C. and pH 5.5. Therefore, a thermostable cellobiohydrolase can be obtained by having any of the polypeptides (A) to (L) as the cellobiohydrolase catalytic region. In particular, since it exhibits high cellobiohydrolase activity even at 70 to 100 ° C., any of the polypeptides (D) to (L) is preferably used as the cellobiohydrolase catalytic region.
- thermostable cellobiohydrolase uses phosphoric acid swollen Avicel (PSA) as a substrate.
- PSA phosphoric acid swollen Avicel
- the thermostable cellobiohydrolase may use a ⁇ -glucan other than PSA as a substrate.
- the other ⁇ -glucan include, for example, Lichenan, Avicel composed of ⁇ -1,3 bond and ⁇ -1,4 bond, crystalline bacterial cellulose (Bacterial microcrystalline cellulose, BMCCC), crystalline cellulose such as filter paper, carboxymethylcellulose, and the like.
- thermostable cellobiohydrolase in addition to PSA, those using at least one of glucan consisting of ⁇ -1,3 bond and ⁇ -1,4 bond and crystalline cellulose as a substrate are preferable. More preferred are glucans composed of ⁇ -1,3 bonds and ⁇ -1,4 bonds, and crystalline cellulose as a substrate.
- thermostable cellobiohydrolase according to the present invention is in the range of pH 4.5 to 6.0 although it varies depending on the reaction temperature.
- the thermostable cellobiohydrolase according to the present invention preferably exhibits cellobiohydrolase activity at least within the range of pH 4.5 to 6.0, and cellobiohydrolase within the range of pH 4.0 to 6.5. Those exhibiting ase activity are more preferable, and those exhibiting cellobiohydrolase activity within the range of pH 3.5 to 7.0 are more preferable.
- thermostable cellobiohydrolase according to the present invention may have a cellulose hydrolysis activity other than the cellobiohydrolase activity.
- Other cellulose hydrolyzing activities include endoglucanase activity, xylanase activity, or ⁇ -glucosidase activity.
- thermostable cellobiohydrolase according to the present invention may be an enzyme consisting only of the cellobiohydrolase catalytic region consisting of any of the polypeptides (A) to (L), and includes other regions. May be. Examples of the other region include regions other than the cellobiohydrolase catalyst region of known cellobiohydrolase.
- the thermostable cellobiohydrolase according to the present invention includes an enzyme obtained by substituting the cellobiohydrolase catalytic region with the polypeptides (A) to (L) as compared to known cellobiohydrolase. Is also included.
- thermostable cellobiohydrolase according to the present invention includes a region other than the cellobiohydrolase catalyst region, it is preferable to include a cellulose-binding module.
- the cellulose binding module may be upstream (N-terminal side) or downstream (C-terminal side) of the cellobiohydrolase catalytic region.
- the cellulose binding module and the cellobiohydrolase catalyst region may be directly bonded or may be bonded via a linker region having an appropriate length.
- the thermostable cellobiohydrolase according to the present invention is preferably one in which a cellulose binding module is present via a linker region upstream or downstream of the cellobiohydrolase catalyst region, and upstream of the cellobiohydrolase catalyst region. It is more preferable that the cellulose binding module is present via a linker region.
- the cellulose binding module contained in the thermostable cellobiohydrolase according to the present invention may be a region having binding ability with cellulose, for example, binding ability with PSA or crystalline Avicel, and its amino acid sequence is particularly limited. It is not a thing.
- bonding module you may use the cellulose coupling module which a known protein has, or what changed it suitably, for example.
- the cellulose binding module includes a polypeptide comprising 148 amino acids (T35-P182) from threonine (T) at position 35 to proline (P) at position 182 of the amino acid sequence represented by SEQ ID NO: 11. Or a polypeptide having an amino acid sequence in which one or more amino acids in the polypeptide are deleted, substituted or added, and having a cellulose-binding ability.
- thermostable cellobiohydrolase according to the present invention has a cellobiohydrolase catalytic region and a cellulose binding module, it is preferable that these are bonded via a linker sequence.
- the amino acid sequence of the linker sequence, its length, etc. are not particularly limited. Specific examples of such a linker sequence include, for example, 112 amino acids (S183-T294) from serine (S) at position 183 to threonine (T) at position 294 in the amino acid sequence represented by SEQ ID NO: 11. Or a polypeptide having an amino acid sequence in which one or more amino acids in the polypeptide are deleted, substituted or added.
- the amino acid sequence represented by SEQ ID NO: 11 is the open reading frame OJ1-1 obtained from the high temperature hot spring soil metagenomic DNA and the novel gene OJ1-1-1 obtained therefrom by PCR cloning in Example 1 described later.
- 11 is an amino acid sequence of a polypeptide encoded by 11; 148 amino acids (T35-P182) from threonine at position 35 to proline at position 182 of OJ1-1-11 are cellulose-binding module CBM3, and 112 amino acids (S183 from serine (S) at position 183 to threonine at position 294).
- -T294) is considered to be a linker sequence.
- thermostable cellobiohydrolase has, at the N-terminus or C-terminus, a signal peptide that can be localized by moving to a specific region in the cell, or a signal peptide that is secreted outside the cell. You may do it.
- a signal peptide include an apoplast transfer signal peptide, an endoplasmic reticulum retention signal peptide, a nuclear transfer signal peptide, and a secretory signal peptide.
- the apoplast transfer signal peptide is not particularly limited as long as it is a peptide capable of transferring a polypeptide to an apoplast, and a known apoplast transfer signal peptide can be appropriately used.
- the apoplast transfer signal peptide include a potato protease inhibitor II signal peptide (see, for example, Wang et al., 2005, Transgenic Research, Vol. 14, pages 167 to 178).
- the endoplasmic reticulum retention signal peptide is not particularly limited as long as it is a peptide capable of retaining the polypeptide in the endoplasmic reticulum, and a known endoplasmic reticulum retention signal peptide can be appropriately used.
- the endoplasmic reticulum retention signal peptide include a signal peptide consisting of the amino acid sequence of HDEL.
- thermostable cellobiohydrolase according to the present invention has other tags added to the N-terminus and C-terminus, for example, so that it can be easily purified when produced using an expression system. Also good.
- tags commonly used in the expression and purification of recombinant proteins such as His tag, HA (hemagglutinin) tag, Myc tag, and Flag tag can be used.
- thermostable cellobiohydrolase encodes the thermostable cellobiohydrolase which is the first aspect of the present invention.
- the thermostable cellobiohydrolase can be produced by using an expression system of the host by introducing an expression vector incorporating the polynucleotide into the host.
- the polynucleotide according to the second aspect of the present invention is a polynucleotide having a region encoding a cellobiohydrolase catalytic region consisting of any one of the following base sequences (a) to (n): is there.
- A A base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 1.
- B consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5
- a nucleotide sequence encoding a polypeptide having ase activity is there.
- A A base sequence encoding a polypeptide consisting of the amino acid sequence represented by SEQ ID NO: 1.
- B consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 1 have been deleted, substituted or added, and cellobiohydro
- (E) consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 3 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5 A nucleotide sequence encoding a polypeptide having ase activity.
- H It consists of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 5 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5.
- K consisting of an amino acid sequence in which one or more amino acids of the amino acid sequence represented by SEQ ID NO: 7 have been deleted, substituted or added, and cellobiohydro under conditions of at least 75 ° C. and pH 5.5
- N a nucleotide sequence of a polynucleotide that hybridizes under stringent conditions with a polynucleotide comprising the nucleotide sequence represented by SEQ ID NO: 2, 4, 6, or 8, and at least at 75 ° C. and pH 5.5
- SEQ ID NO: 2, 4, 6, or 8 a nucleotide sequence represented by SEQ ID NO: 2, 4, 6, or 8, and at least at 75 ° C. and pH 5.5
- stringent conditions include, for example, a method described in Molecular Cloning-A LABORATORY MANUAL THIRD EDITION (Sambrook et al., Cold Spring Harbor Laboratory Press).
- 6 ⁇ SSC composition of 20 ⁇ SSC: 3M sodium chloride, 0.3M citric acid solution, pH 7.0
- 5 ⁇ Denhardt solution composition of 100 ⁇ Denhardt solution: 2% by weight bovine serum albumin, 2% by weight
- the washing buffer used for washing after incubation is preferably a 0.1 ⁇ SSC solution containing 0.1% by mass SDS, and more preferably a 0.1 ⁇ SSC solution containing
- the base sequence of (a) may be the base sequence represented by SEQ ID NO: 2, and the base sequence represented by SEQ ID NO: 2 is not changed in the amino acid sequence in the host.
- the base sequence may be modified to a frequently used codon.
- the base sequences of (d), (g), and (j) may be the base sequences represented by SEQ ID NOs: 4, 6, and 8, respectively.
- the base sequence may be modified from a heavy codon to a codon that is more frequently used in the host. Codon modification can be performed by a known gene recombination technique.
- the polynucleotide comprising the base sequence represented by SEQ ID NO: 2, 4, 6, or 8 may be chemically synthesized based on the base sequence information, such as AR19G-166-RA, AR19G-166-QV, etc.
- the full length of a gene to be encoded (sometimes referred to as “AR19G-166 gene”) or a partial region including a cellobiohydrolase catalytic region may be obtained from nature by gene recombination techniques.
- the full length of AR19G-166 gene or a partial region thereof is represented by SEQ ID NO: 2, 4, 6, or 8 using, for example, a sample containing a microorganism from nature and using genomic DNA collected from the sample as a template.
- CDNA synthesized by reverse transcription using the mRNA recovered from the sample as a template may be used as a template.
- recovers the nucleic acid used as a template is a sample extract
- the sequence identity with the base sequence represented by SEQ ID NO: 2, 4, 6, or 8 is not particularly limited as long as it is 80% or more and 100% or less, but 85% or more and 100%. % Or less, more preferably 90% or more and 100% or less, and still more preferably 95% or more and 100% or less.
- sequence identity between base sequences is obtained by aligning two base sequences side by side with a gap in the portion corresponding to insertion and deletion so that the corresponding bases most closely match. It is determined as the ratio of the matched base to the entire base sequence excluding the gap in the middle.
- sequence identity between base sequences can be determined using various homology search software known in the technical field.
- sequence identity value of the base sequence in the present invention is obtained by calculation based on the alignment obtained by the known homology search software BLASTN.
- the polynucleotide comprising the base sequence of (b), (c), (e), (f), (h), (i), (k), (l), or (m), respectively, It can be artificially synthesized by deleting, substituting or adding one or more bases to the polynucleotide comprising the base sequence represented by SEQ ID NO: 2, 4, 6, or 8.
- the base sequence of (b), (c), (e), (f), (h), (i), (k), or (l) includes the full length of the homologous gene of the AR19G-166 gene. It may be a sequence or a partial sequence thereof.
- the homologous gene of the AR19G-166 gene can be obtained by a gene recombination technique used when obtaining a homologous gene of a gene whose base sequence is known.
- a base is deleted in a polynucleotide means that a part of the nucleotide constituting the polynucleotide is lost (removed).
- substitution of a base in a polynucleotide means that the base constituting the polynucleotide is changed to another base.
- a base is added in a polynucleotide means that a new base is inserted into the polynucleotide.
- Artificially synthesize a polynucleotide comprising the base sequence (b), (c), (e), (f), (h), (i), (k), (l), or (m).
- the number of bases deleted, substituted or added to the base sequence represented by SEQ ID NO: 2, 4, 6, or 8 is the same as the base sequence of the synthesized polynucleotide, SEQ ID NO: 2, 4, although it is not particularly limited as long as it has 80% or more and less than 100% sequence identity with the base sequence represented by 6 or 8, it is preferably 1 to 256, more preferably 1 to 192, and 1 to 128. More preferably, 1 to 64 is particularly preferable.
- the polynucleotide according to the second aspect of the present invention may have only a region encoding a cellobiohydrolase catalytic region.
- a cellulose-binding module, a linker sequence, various signal peptides, You may have the area
- the expression vector according to the third aspect of the present invention incorporates the polynucleotide according to the second aspect of the present invention, and the cellobiohydrolase activity in a host cell under the conditions of at least 75 ° C. and pH 5.5.
- an expression vector is a vector comprising, from upstream, DNA having a promoter sequence, DNA having a sequence for incorporating foreign DNA, and DNA having a terminator sequence.
- the expression vector from the upstream as an expression cassette comprising DNA having a promoter sequence, the polynucleotide of the second aspect of the present invention, and DNA having a terminator sequence.
- the polynucleotide can be incorporated into the expression vector by using a well-known gene recombination technique, and a commercially available expression vector preparation kit may be used.
- the expression vector may be introduced into prokaryotic cells such as Escherichia coli or actinomycetes, or introduced into eukaryotic cells such as yeast, filamentous fungi, insect cultured cells, cultured mammalian cells, plant cells, etc. It may be.
- prokaryotic cells such as Escherichia coli or actinomycetes
- eukaryotic cells such as yeast, filamentous fungi, insect cultured cells, cultured mammalian cells, plant cells, etc. It may be.
- any expression vector usually used according to each host can be used.
- thermostable cellobiohydrolase examples include binary vectors such as pIG121 and pIG121Hm.
- promoters examples include nopaline synthase gene promoter and cauliflower mosaic virus 35S promoter.
- usable terminators include nopaline synthase gene terminators.
- promoters specific to tissues and organs may be used. By using such a tissue or organ-specific promoter, the thermostable cellobiohydrolase can be expressed only in a specific tissue or organ, not in the whole plant. For example, in a non-edible part of an edible plant Only thermostable cellobiohydrolase can be expected to be expressed.
- the expression vector according to the present invention is preferably an expression vector in which not only the polynucleotide of the second aspect of the present invention but also a drug resistance gene or the like is incorporated. This is because it is possible to easily select a plant transformed with an expression vector and a plant not transformed.
- the drug resistance gene include a kanamycin resistance gene, a hygromycin resistance gene, and a bialaphos resistance gene.
- thermostable cellobiohydrolase of the first aspect of the present invention can be expressed.
- Conventionally known cellobiohydrolases have a narrow range of current hosts, that is, many of them are difficult to heterologously express.
- the thermostable cellobiohydrolase according to the present invention can be expressed in a wide range of expression hosts such as Escherichia coli, actinomycetes, yeast, filamentous fungi, and higher plant chloroplasts.
- the method for producing a transformant using an expression vector is not particularly limited, and can be carried out by a method usually used for producing a transformant.
- Examples of the method include an Agrobacterium method, a particle gun method, an electroporation method, and a PEG (polyethylene glycol) method.
- a host is a plant cell, it is preferable to carry out by the particle gun method or the Agrobacterium method.
- the host into which the expression vector is introduced may be a prokaryotic cell such as Escherichia coli or actinomycete, or a eukaryotic cell such as yeast, filamentous fungus, insect cultured cell, cultured mammalian cell, or plant cell.
- a prokaryotic cell such as Escherichia coli or actinomycete
- a eukaryotic cell such as yeast, filamentous fungus, insect cultured cell, cultured mammalian cell, or plant cell.
- thermostable cellobiohydrolase when the transformant is a filamentous fungus such as Aspergillus or a eukaryotic microorganism (or eukaryote) such as yeast, mass production of thermostable cellobiohydrolase with higher heat resistance is relatively simple. can do.
- the transformed plant into which the expression vector of the third aspect of the present invention has been introduced has a relatively large amount of thermostable cellobiohydrolase according to the present invention produced per individual, It is also possible to cultivate in large quantities, such as outdoors.
- the transformed plant since the transformed plant originally contains thermostable cellobiohydrolase in the plant body, it is suitable as a biomass resource.
- the host cell for expressing the thermostable cellobiohydrolase according to the present invention is preferably at least one host cell selected from the group consisting of Escherichia coli, yeast, filamentous fungi, actinomycetes, and plants. More preferred is at least one host cell selected from the group consisting of fungi, actinomycetes, and plants, and even more preferred are plants.
- the obtained transformant is generally used in the same manner as the host before transformation. It can be cultured by the method.
- a plant cultured cell may be used as a host, or a plant organ or a plant tissue may be used.
- a transformed plant can be obtained from transformed plant cells or callus.
- a transformed plant cell can be obtained by culturing a transformed plant cell using a hormone-free regeneration medium or the like, and transplanting and cultivating the obtained rooted young plant body to soil or the like. it can.
- the expression cassette for expressing the thermostable cellobiohydrolase according to the present invention derived from the expression vector according to the third aspect of the present invention is a plant nuclear genome. May be incorporated into the chloroplast genome, but is preferably incorporated into the chloroplast genome.
- the chloroplast transformant since the inserted foreign gene is cytoplasmically inherited, it is possible to prevent environmental leakage of the recombinant gene through pollen. In large-scale production of transformed plants by field cultivation, there is concern about environmental leakage of recombinant genes, but chloroplast transformants can suppress environmental leakage of recombinant genes more than nuclear genome transformants. There is an advantage in that.
- the transformant according to the present invention when the transformant according to the present invention is a plant, the transformant includes the thermostable cellobiohydrolase according to the present invention in the same manner as the plant in addition to the plant directly obtained by transformation. Also included are plants that are descendants of the plant in which they are expressed.
- the plant progeny means a plant obtained by germinating seeds obtained from a plant, a plant obtained by cutting, and the like.
- the type of plant used as a host is not particularly limited, and may be a dicotyledonous plant, a monocotyledonous plant, a fern or a moss, and an algae or microalgae. It may be.
- plants belonging to Brassicaceae, Gramineae, Eggplant, Legume, Asteraceae, Convolvulaceae, Euphorbiaceae and the like can be mentioned. Since it is a plant suitable for transformation via Agrobacterium, a plant of the family Solanaceae, Brassicaceae or Gramineae is preferable.
- solanaceous plants include tobacco, eggplant, potato, tomato, and bell pepper.
- Examples of the Brassicaceae plants include Arabidopsis thaliana, rape, solouna, radish, cabbage, and wasabi.
- Examples of the grass family include rice, corn, sorghum, wheat, barley, rye, and millet. Other leguminous plants include peanuts, chickpeas, soybeans, kidney beans, and the like.
- Examples of asteraceae plants include burdock, mugwort, calendula, cornflower, sunflower and the like.
- Examples of the Convolvulaceae plant include the convolvulus, the convolvulus, the prunus, and the convolvulus.
- Examples of Euphorbiaceae plants include Euphorbiaceae, Nuttodai, Takatodai, and the like. When the transformant according to the present invention is a plant, among these, a monocotyledonous plant is preferable, a grass family plant is more preferable, and a grass family plant with a large amount of biomass is further preferable
- thermostable cellobiohydrolase The method for producing a thermostable cellobiohydrolase according to the fifth aspect of the present invention is a method for producing a thermostable cellobiohydrolase in the transformant according to the fourth aspect of the present invention.
- the present invention relates to Thermostable cellobiohydrolase is constantly expressed.
- thermostable cellobiohydrolase is expressed in the transformant.
- thermostable cellobiohydrolase produced by the transformant may be used while remaining in the transformant, or may be extracted and purified from the transformant.
- the method for extracting and purifying the thermostable cellobiohydrolase from the transformant is not particularly limited as long as it does not impair the activity of the thermostable cellobiohydrolase.
- it can extract by the method normally used.
- Examples of the method include a method in which the transformant is immersed in an appropriate extraction buffer to extract heat-resistant cellobiohydrolase, and then separated into an extract and a solid residue.
- the extraction buffer preferably contains a solubilizer such as a surfactant.
- the transformant is a plant, the transformant may be shredded or pulverized in advance before being immersed in the extraction buffer.
- thermostable cellobiohydrolase in the extract can be purified using a known purification method such as a salting out method, an ultrafiltration method, or a chromatography method.
- thermostable cellobiohydrolase according to the present invention When the thermostable cellobiohydrolase according to the present invention is expressed in a state having a secretory signal peptide in the transformant, the transformant is cultured from the obtained culture after culturing the transformant. By collecting the removed culture supernatant, a solution containing a thermostable cellobiohydrolase can be easily obtained.
- the thermostable cellobiohydrolase according to the present invention has a tag such as a His tag
- the thermostable cellobiohydrolase in the extract or culture supernatant is obtained by affinity chromatography using the tag. Can be easily purified.
- the method for producing the thermostable cellobiohydrolase of the present invention comprises expressing the thermostable cellobiohydrolase in the transformant according to the fourth aspect of the present invention, and, if desired, the thermostable from the transformant. Extraction and purification of cellobiohydrolase.
- the cellulase mixture according to the sixth aspect of the present invention is a heat-resistant cellobiohydrolase according to the first aspect of the present invention or a heat-resistant cellobiohydrolase produced according to the method according to the fifth aspect. It contains sex cellobiohydrolase and at least one other cellulase.
- the thermostable cellobiohydrolase produced by the method for producing a thermostable cellobiohydrolase of the fifth aspect may be contained in a transformant, and extracted and purified from the transformant. It may be what was done.
- the cellulase other than the thermostable cellobiohydrolase contained in the cellulase mixture is not particularly limited as long as it has a hydrolysis activity of cellulose.
- examples thereof include hemicellulases such as xylanase and ⁇ -xylosidase, ⁇ -glucosidase, endoglucanase and the like.
- the cellulase mixture according to the present invention preferably contains at least one of hemicellulase and endoglucanase, and more preferably contains both hemicellulase and endoglucanase.
- those containing one or more cellulases selected from the group consisting of xylanase, ⁇ -xylosidase, ⁇ -glucosidase, and endoglucanase are preferable, and all containing xylanase, ⁇ -xylosidase, ⁇ -glucosidase, and endoglucanase Is more preferable.
- the other cellulase contained in the cellulase mixture is preferably a thermostable cellulase having cellulase activity at least at 70 ° C., and more preferably a thermostable cellulase having cellulase activity at 70 to 90 ° C. Since all the enzymes contained in the cellulase mixture are heat resistant, the cellulose decomposition reaction by the cellulase mixture can be efficiently performed under high temperature conditions.
- the cellulase mixture when the cellulase mixture contains only a thermostable cellulase, the cellulase mixture can be used for lignocellulose saccharification treatment, whereby a lignocellulose hydrolysis reaction can be performed in a high-temperature environment at a saccharification temperature of 70 to 90 ° C. .
- a lignocellulose hydrolysis reaction can be performed in a high-temperature environment at a saccharification temperature of 70 to 90 ° C. .
- the manufacturing method of the cellulose degradation product which is the 7th aspect of this invention is a method of decomposing
- a material containing cellulose is used as the thermostable cellobiohydrolase of the first aspect of the present invention, the transformant of the fourth aspect of the present invention, or the thermostable cello of the fifth aspect of the present invention.
- a cellulose degradation product is produced by contacting with the thermostable cellobiohydrolase produced by the biohydrolase production method.
- the “cellulose degradation product” in the present invention and the present specification includes cellobiose.
- the material containing cellulose is not particularly limited as long as it contains cellulose.
- Examples of the material include cellulosic biomass such as weeds and agricultural waste, and waste paper.
- physical treatment such as crushing and shredding, chemical treatment such as acid and alkali, immersion or dissolution treatment in an appropriate buffer Etc. are preferably performed.
- the reaction conditions for the hydrolysis reaction of cellulose by the thermostable cellobiohydrolase according to the present invention may be any conditions as long as the thermostable cellobiohydrolase exhibits cellobiohydrolase activity.
- the reaction is preferably performed at 55 to 80 ° C. and pH 3.5 to 7.0, and more preferably at 70 to 100 ° C. and pH 4.0 to 6.0.
- the reaction time is appropriately adjusted in consideration of the type of material containing cellulose subjected to hydrolysis, the pretreatment method, the amount, and the like. For example, when cellulosic biomass is decomposed for 10 minutes to 100 hours, the reaction time can be 1 to 100 hours.
- the hydrolysis reaction of cellulose it is also preferable to use at least one other cellulase in addition to the heat-resistant cellobiohydrolase according to the present invention.
- the other cellulase the same cellulase as that contained in the cellulase mixture can be used, and it is preferably a thermostable cellulase having cellulase activity at least at 70 ° C., preferably at least 70 to 100 ° C.
- the method for producing a cellulose degradation product includes the heat-resistant cellobiohydrolase according to the first aspect of the present invention, the transformant according to the fourth aspect of the present invention, or the heat resistance according to the fifth aspect.
- the thermostable cellobiohydrolase produced by the method for producing cellobiohydrolase, the cellulase mixture of the sixth aspect of the present invention may be used.
- a method for producing a polynucleotide encoding a thermostable cellobiohydrolase according to the eighth aspect of the present invention comprises a base represented by SEQ ID NO: 12 using a biologically-derived DNA or a biologically-derived RNA reverse transcription product as a template.
- a forward primer (primer according to the ninth aspect of the present invention) comprising a sequence or a base sequence in which one or more bases are added to the 5 ′ end of the base sequence represented by SEQ ID NO: 12; and SEQ ID NO: 13
- a reverse primer consisting of a base sequence in which one or more bases are added to the 5 ′ end of the base sequence represented by SEQ ID NO: 13 (primer according to the tenth aspect of the present invention) Is used to obtain a polynucleotide containing a base sequence encoding thermostable cellobiohydrolase as an amplification product.
- the base sequence represented by SEQ ID NO: 12 is a base sequence that is homologous (identical) to a partial sequence consisting of bases 1 to 22 in the base sequence represented by SEQ ID NO: 2.
- the base sequence represented by SEQ ID NO: 13 is a base sequence complementary to a partial sequence consisting of bases at positions 1263 to 1284 of the base sequence represented by SEQ ID NO: 2. For this reason, a primer comprising the base sequence represented by SEQ ID NO: 12 is used as a forward primer, and a primer comprising the base sequence represented by SEQ ID NO: 13 is used as a reverse primer.
- a polynucleotide encoding the cellobiohydrolase catalytic region of the AR19G-166 gene by performing PCR using a nucleotide as a template (for example, a polynucleotide consisting of a base sequence represented by SEQ ID NO: 2, 4, 6, or 8) Can be obtained as an amplification product.
- the 5 'end of the primer may have an additional base sequence that is not used for hybridization with the template.
- a forward primer consisting of a base sequence in which one or more bases are added to the 5 ′ end of the base sequence represented by SEQ ID NO: 12, and 1 or 5 at the 5 ′ end of the base sequence represented by SEQ ID NO: 13
- a reverse primer consisting of a base sequence to which a plurality of bases are added
- one or more of the forward primer-derived ones at the 5 ′ end of the region encoding the cellobiohydrolase catalytic region of the AR19G-166 gene A polynucleotide to which a base is added and one or more bases derived from the reverse primer are added to the 3 ′ end can be obtained.
- each primer examples include, for example, a sequence required for incorporating an amplification product into an expression vector, a restriction enzyme site, a base sequence encoding a tag, and a base encoding a signal peptide. Examples include sequences. It is also preferable to add initiation methionine (ATG) to the 5 'end of the base sequence represented by SEQ ID NO: 12.
- ATG initiation methionine
- the DNA used as a template for PCR is a reverse transcription product (cDNA) of biological DNA or biological RNA.
- the organism may be a microorganism artificially introduced with a plasmid in which a polynucleotide encoding the cellobiohydrolase catalytic region of the AR19G-166 gene is artificially introduced, or the transformant, and a sample collected from nature It may be an organism contained therein.
- the sample is preferably a sample collected from a high temperature environment such as hot spring soil.
- PCR conditions and the like can be appropriately determined by those skilled in the art in consideration of the type of polymerase to be used. If the nucleic acid used as a template contains genomic DNA of the AR19G-166 gene or cDNA synthesized from the mRNA of the gene, the PCR encodes the cellobiohydrolase catalytic region of the AR19G-166 gene.
- the polynucleotide to be obtained can be obtained as an amplification product.
- the amino acid sequence of the cellobiohydrolase catalytic region is highly conserved among homologous genes. Therefore, when the nucleic acid used as a template contains genomic DNA of the homologous gene of AR19G-166 gene or cDNA synthesized from mRNA of the homologous gene by using the forward primer and the reverse primer.
- the polynucleotide encoding the cellobiohydrolase catalytic region of the AR19G-166 gene homolog gene can be obtained as an amplification product by the polynucleotide production method of the present invention.
- a gene synthesized from a genomic DNA of a gene other than the AR19G-166 gene homologous gene and having a base sequence similar to the AR19G-166 gene or mRNA of the homologous gene is included. If it is contained, the polynucleotide encoding the entire region or a partial region of the gene can be obtained as an amplification product by the method for producing a polynucleotide according to the present invention. Therefore, the method for producing a polynucleotide according to the present invention is also useful for cloning a novel cellobiohydrolase having an amino acid sequence similar to the AR19G-166 gene.
- thermostable cellobiohydrolase Cloning of novel thermostable cellobiohydrolase from hot spring soil ⁇ 1> DNA extraction from hot spring soil and whole genome sequence (Whole Genome Sequence, WGS) Collect soil DNA from neutral to weak alkaline hot springs for the purpose of gene search for thermostable cellobiohydrolase (optimum temperature: 55 ° C or higher) and super thermostable cellobiohydrolase (optimum temperature: 80 ° C or more) The base sequence of the microbiota metagenomic DNA constituting these soils was then deciphered.
- DNA was extracted from 10 g of each collected hot spring soil sample using a DNA extraction kit (ISOIL Large for Beads ver. 2, manufactured by NIPPON GENE). Among genomic samples obtained with a DNA amount of 10 ⁇ g or more, 5 ⁇ g was used, and metagenomic sequencing was performed. That is, a shotgun sequence of metagenomic DNA and 16srDNA amplicon was performed on the extracted DNA using GS FLX Titanium 454 manufactured by Roche Diagnostics. The remaining DNA was used for PCR cloning of the cellulase gene.
- ISOIL Large for Beads ver. 2 manufactured by NIPPON GENE
- genomic amplification was performed using a genomic DNA amplification kit (GenomiPhi V2 DNA Amplification Kit, manufactured by GE Healthcare). The sequence was decoded. Decode the metagenomic DNA 3 to 4 times for each hot spring soil sample, a total of 19 times.
- Whole genome sequence (WGS) with an average read length of 394 bp, total number of reads 26,295,463, and total genome decoding amount 10.3 Gbp A data set was obtained.
- the quality filtered lead and the assembly contig of 100 bp or more were 2.5 Gbp in total, and this data set was used for cellulase enzyme gene analysis.
- the total number of leads 26,294,193, 17,991,567 were assembled on average with 1 kb or more contigs (total 595,602 contigs), of which the maximum contig length was 278,185 bp.
- Open reading frame (ORF) prediction of cellobiohydrolase EC number is 3.2.1.4 (cellulose) from UniProt database (http://www.uniprot.org/) 3.2.1. Download the sequence of 37 ( ⁇ -xylosidase), 3.2.1.91 (cellulose 1,4- ⁇ -cellobiosidase), 3.2.1.8 (endo 1,4- ⁇ -xylanase) (access date) : 2009/4/13), a proteome local database of these glycoside hydrolase genes was constructed.
- sequences having a coding region of 100 bp or less were removed.
- the target contig is referred to the hit enzyme sequence on the local database, and the frame shift of the sequence is corrected by inserting or deleting a gap so that the alignment score is maximized.
- Protein glycoprotein hydrolase such as cellulase, endohemicellulase, debranching enzyme and the like thus obtained is a protein functional region sequence database pfam HMMs (Pfam version 23.0 and HMMER v2.3; Finn et al., Nucleic Acids Research Database). , 2010, Issue 38, p. D211-222). More specifically, a sequence homology search algorithm HMMER (Hurricane Markov model) (Durbin et al., 'The theory behind profile HMMs. Biological sequence analysis: probabilistic models of proteins and nucleic acids', 1998, Cambridge University Press .; hmmpfam (Ver.
- Orphelia detects ORF using the rare codons GTG (valine), TTG (leucine), and ATA (isoleucine) in addition to ATG (methionine). For this reason, if the assembled contig does not include a full-length ORF with ATG as the start codon, an error occurs in Orphelia that recognizes the rare codon as the start codon.
- GTG valine
- TTG leucine
- ATA isoleucine
- the results of GH family classification of 44 ORFs estimated to be cellobiohydrolase genes are shown in Table 1.
- Table 1 the numbers in parentheses represent the number of full-length ORFs starting from methionine.
- two cellobiohydrolase ORFs belonging to the GH6 family are from metagenome AR19 (AR19G-166 and AR19G-12) and from metagenome OJ1 (OJ1-1 and OJ1-2), a total of four Obtained.
- an ORF sequence belonging to the GH7 family was not obtained.
- 15 and 12 ORFs belonging to the GH9 and GH48 families were obtained, respectively.
- the cellulase enzyme solution for biofuels currently in practical use is Novozyme CELLIC (registered trademark) CTec2 (http://www.bioenergy.novozymes.com/cellulosic-ethanol/), Genencor Accelerase (registered trademark). TRIO (http://www.genencor.com/industries/biofuels/fuel_ethanol_from_biomass_cellulosic_biofuels/), which is based on an enzyme secreted by the wood-decaying fungus Trichoderma reesei.
- the main constituent enzymes of glycoside hydrolase (GH) secreted by this filamentous fungus are cellobiohydrolases CBHI and CBHII, which belong to the GH7 family and GH6 family, respectively.
- Open reading frames OJ1-1 and OJ1-2 The open reading frame OJ1-1 encoded a multidomain enzyme consisting of 548 amino acids and having a cellulose binding module CBM3 (149 bp) -linker (111 bp) -GH6 catalytic domain. However, the latter half of the catalytic region lacked a stop codon and was incomplete.
- this cellulose binding module sequence has 63% sequence identity in terms of amino acid sequence with the cellulose binding module CBM3 (SEQ ID NO: 16) possessed by cellobiohydrolase (Genbank: AAF22273.1) of the thermophilic aerobic bacterium Caldibacillus cellulovorans. A novel CBM3 sequence shown.
- the cellobiohydrolase catalytic region of OJ1-1 shows 58% sequence identity in amino acid sequence with cellulose 1,4- ⁇ -cellobiosidase (Genbank: ADJ46954.1) of Amycolatopsis mediterranei U32 and has a strong cellulase enzyme.
- the amino acid sequence showed 48% sequence identity with ⁇ -1,4-cellobiohydrolase (Genbank: AAA622211.1) of the thermophilic actinomycetes Thermobifida fusca YX.
- OJ1-1-11 One gene clone (OJ1-1-11) was obtained from OJ1-1 by PCR cloning.
- OJ1-1-11 consists of 548 amino acids, and 32 amino acids (M1-A32) from the start codon methionine (M) (position 1) to alanine at position 32 are secretion signals (signalP 4.0), 35 148 amino acids (T35-P183) from threonine at position 182 to proline at position 182 are cellulose binding module CBM3, and 112 amino acids (S183-T294) from serine (S) at position 183 to threonine at position 294 are linker sequences.
- M1-A32 32 amino acids from the start codon methionine (M) (position 1) to alanine at position 32 are secretion signals (signalP 4.0)
- 35 148 amino acids (T35-P183) from threonine at position 182 to proline at position 182 are cellulose binding module CBM3
- the open reading frame OJ1-2 was a base sequence encoding a polypeptide consisting of 247 amino acids and consisting only of the GH6 catalytic region.
- OJ1-2 is an incomplete sequence because OJ1-2 lacks both the start and stop codons, and cellobiohydrolase of the GH6 family is usually composed of 400 or more amino acids.
- the amino acid sequence deduced from OJ1-2 is 100% identical to the amino acid sequence of AR19G-12. Therefore, OJ1-2 is the same gene as AR19G-12 and is a partial sequence of AR19G-12. it is conceivable that.
- the gene clone obtained from OJ1-2 by PCR cloning incorporated its catalytic region into a transformation vector and expressed it in E. coli. As a result, no enzyme activity was obtained for both PSA and CMC substrates.
- Open reading frames AR19G-166 and AR19G-12 The open reading frame AR19G-166 encoded a polypeptide consisting of 474 amino acids (SEQ ID NO: 9), but was an incomplete length sequence in which the start codon was lost, only the partial sequence of the linker and the GH6 catalytic region. Consisted of.
- the GH6 catalytic region of AR19G-166 showed 66% amino acid sequence identity with the glucoside hydrolase (Genbank: ABX047776.1) of the Chloroflexus mesophilic aerobic bacterium Herpetosiphon aurantiacus DSM 785.
- AR19G-166-RA and AR19G-166-QV differed only in the two amino acids at positions 299 and 351.
- the amino acid at position 299 was arginine and the amino acid at position 351 was alanine (SEQ ID NO: 1).
- the amino acid at position 299 was glutamine, and the amino acid at position 351 was valine (SEQ ID NO: 3).
- the open reading frame AR19G-12 encoded a polypeptide consisting of 459 amino acids (SEQ ID NO: 10). Like AR19G-166, the open reading frame AR19G-12 is an incomplete length sequence in which the start codon is lost. And the GH6 catalyst region. The GH6 catalytic region of AR19G-12 showed 64% amino acid sequence identity with Herpetosiphon aurantiacus DSM 785 family 6 glucoside hydrolase (Genbank: ABX04776.1). However, when a gene clone obtained by PCR from AR19G-12 was incorporated into a transformation vector and expressed in E. coli, no enzyme activity was obtained for either PSA or CMC substrate.
- FIG. 1 is a rooted molecular phylogenetic tree of exo-type glucoside hydrolases (cellobiohydrolase, glucoside hydrolase, exoglucanase, and cellobiosidase) belonging to the GH6 family.
- homology search was performed on Genbank by BLASTP, and the sequence of 21 family 6 exo-type glucoside hydrolases was obtained.
- the endoglucanase Thermobifida fusca YX Cel6A (Genbank: AAC063888.1) belonging to the GH6 family was out-group.
- the bootstrap probability was calculated from 1,000 replicas and indicated as a percentage at each branch point of the phylogenetic tree. In FIG. 1, the scale shown at the bottom is the genetic distance (average number of amino acid substitutions / site).
- the enzyme name “CBH” in parentheses is an abbreviation for cellobiohydrolase
- GH is an abbreviation for glucoside hydrolase.
- the bacterial and filamentous fungal family 6 glucoside hydrolases used for the phylogenetic tree reference are as follows (in parentheses are Genbank, Protein Data bank (PDB) or EMBL-Bank accession numbers).
- Fungal Family 6 glycoside hydrolase Acremonium cellulolyticus Y-94 cellobiohydrolase II (Genbank: BAA74458.1); Agaricus bisporus cellobiohydrolase (Genbank: AAA50608.1); Aspergillus kawachii IFO 4308 1,4-beta-D-glucan cellobiohydrolase C ( Genbank: GAA89571.1); Aspergillus niger ATCC 1015 1,4-beta-D-glucan cellobiohydrolase C (Genbank: EHA25828.1); Chathemium thermophile um cellobiohydrolase family 6 (Genbank: AAW64927.1); Colletotrichum higginsianum glucoside hydrolase family 6 (Genbank: CCF33252.1); Fo
- Bacterial family 6 glucoside hydrolase Acidothermus cellulolyticus 11B glucoside hydrolase family 6 (Genbank: ABK52388. 1); cellobiohydrolase (Genbank: AEE 46055.1); Cellvibrio japonicus Ueda 107 cellobiohydrolase cel6A (Genbank: ACE85978.1); Herpetosiphonau antiacus DSM 785 glucoside hydrolase family 6 (Genbank: ABX04776.1); Jonesia denitrificans DSM 20603 glucoside hydrolase family 6 (Genbank: ACV08399.1); Ktedonobacter racemifer DSM 44963 1,4-beta-cellobiohydrolase (Genbank: EFH85864.1); Micromonospora lupini str.
- Bacterial family 6 glucoside hydrolase Acidothermus cellulolyticus 11B glucoside hydrolase family 6 (Genbank: ABK52388. 1); cell
- Lupac 08 1,4-beta-cellobiohydrolase (Genbank: CCH20969.1); Paenibacillus curdlanolyticus YK9 1,4-beta-cellobiohydrolase (Genbank: EFM08880.1); Ralstonia solanacearum Po82 cellobiohydrolase A (Genbank: AEG71050.1); Salinispora arenicola CNS-205 glucoside hydroxyl family 6 (Genbank: ABV997773.1); Stackbrandlanda nasauensis DSM 44728 1,4-beta-cellobiosidase Genbank: ADD42622.1); Stigmatella aurantiaca DW4 / 3-1 exoglucanase A (Genbank: EAU67050.1); Streptomyces avermitilis MA-4680 1,4-beta-cellobiosidase (Genbank: BAC69564.1); Teredinibacter turnerae T7901 cellobiohydr
- raphani 756C exolucanase A (Genbank: AEL08359.1); Xanthomonas oryzae pv. oryzae KACC 10331 1,4-beta-cellobiosidase (Genbank: AAW77289.1); Xylanimonas cellulosilytica DSM 15894 glucoside hydrolase family 6 (Genbank: ACZ30181.1); Xylella fastidiosa Ann-1 cellobiohydrolase A (Genbank: EGO81204.1).
- the exo-type glucoside hydrolase belonging to the GH6 family was divided into two branch groups having a large genetic distance from each other, that is, a branch group derived from bacteria and a branch group derived from filamentous fungi.
- the lower branching group in FIG. 1 is all filamentous fungal family 6 glucoside hydrolase, while the upper branching group is all bacterial family 6 glucoside hydrolase.
- the open reading frames AR19G-166, AR19G-12, and OJ1-1 are all located in the bacterial branch group, Herpetosiphon aurantiacus DSM 785 family 6 glucoside hydrolase, Gram-negative wood-degrading bacterium Cellvibrio japonicus cellobiohydrolase cel6A It constitutes one branch group with cellobiohydrolase of the marine ⁇ proteobacterium Teredinibacter turnerae.
- the four open reading frames (AR19G-166, AR19G-12 (OJ1-2), OJ1-1) belonging to the GH6 family obtained by metagenomic analysis are the thermophilic filamentous fungi Acremonium cellulolyticus, Chaetomium thermophilum, the biodegradable fungus Thermophilidus fusca serosidiotrophic thermotrophic thermoside fungus Thermosidia fusca and the serobioside thermosidiotrophic thermoside fungi Thermosophyllus fuscaside hydrotrophic thermoside fungus DS It was found to be closely related to hydrolase. From this, it is estimated that these four open reading frames belonging to the GH6 family are bacterial cellobiohydrolase genes. OJ1-1 has a bacterial-specific cellulose binding module CBM3 and strongly supports this assumption.
- the Herpetosiphon aurantiacus DSM 785 family 6 glucoside hydrolase that showed high amino acid sequence identity with AR19G-166-RA and AR19G-166-QV is composed of 1128 amino acids.
- the gene starts with a transition signal sequence consisting of 29 amino acids from position 1 to position 29, cellulose binding module CBM2 consisting of 100 amino acids from position 37 to position 136, GH6 catalyst consisting of 370 amino acids from position 241 to position 611
- Each of these GH6 catalytic regions shown by Pfam is composed of 370 amino acid residues, and more than 50 amino acid residues than the catalytic region of bacterial GH6 catalytic region, for example, Thermobifida fusca YX Cel6B composed of 423 amino acid residues. It was considered short and could not cover the actual catalyst area. Therefore, BLASTP was used to search for the GH6 catalytic region of Herpetosiphon aurantiacus DSM 785 that is homologous to Thermobifida fusca YX Cel6B, and as shown in FIG. It consisted of 428 amino acid residues up to glutamine (Q).
- the GH6 catalytic region of OJ1-1 has an incomplete length, but this partial sequence shows 57% amino acid sequence identity to the GH6 catalytic region of AR19G-166, and the family 6CBH (TrCBHII of the filamentous fungus Trichoderma reesei) ) Only 25% sequence identity.
- AR19G-166 has 47 amino acid residues before the GH6 catalytic region sequence. This amino acid sequence was considered to be part of the linker because proline (P) and threonine (T) were repeated many times. Therefore, AR19G-166 was presumed to be a multidomain gene having a cellulose-binding module CBM via a linker sequence upstream of the cellobiohydrolase catalytic region, similar to OJ1-1.
- FIG. 2A shows an amino acid sequence alignment of a polypeptide consisting of an amino acid sequence deduced from open reading frames (AR19G-166, AR19G-12, OJ1-1), and a family 6 glucoside hydrolase of Herpetosiphon aurantiacus DSM 785.
- FIG. 2B shows the amino acid sequence deduced from the open reading frame OJ1-1 and the amino acid sequence alignment of the cellulose-binding module CBM3 (Genbank: AAF22273.1) of the thermophilic aerobic bacterium Caldibacillus cellulovorans.
- CBM3 Genebank: AAF22273.1
- the black-and-white inverted amino acids indicate the regions in which amino acid residues are conserved in all of these amino acid sequences, and the shaded amino acids are mostly partially mutated in these amino acid sequences. A region in which amino acid residues are conserved in an amino acid sequence is shown.
- FIG. 3A shows an amino acid schematic diagram of a polypeptide consisting of an amino acid sequence deduced from open reading frames (AR19G-166, AR19G-12, OJ1-1), and the CBH gene of Herpetosiphon aurantiacus DSM 785.
- FIG. 3B shows the amino acid sequence deduced from the open reading frame OJ1-1 and the amino acid schematic diagram of the cellulose-binding module CBM3 of the thermophilic aerobic bacterium Caldibacillus cellulovorans.
- “catalyst region (part)” and “linker (part)” indicate that only a part of each region is present.
- a candidate cellobiohydrolase gene obtained by PCR cloning is amplified by PCR using a hot spring soil DNA amplified by a genomic DNA amplification kit (GenomiPhi V2 DNA Amplification Kit, manufactured by GE Healthcare) as a template. did.
- the amplified PCR product was inserted into the pET101 / D-TOPO vector of Champion pET Directional TOPO (registered trademark) Expression Kits (manufactured by Invitrogen), and transformed into One Shot TOP10 strain.
- a positive clone was selected by colony PCR, and cultured in an LB liquid medium containing 100 mg / L ampicillin at 37 ° C. and 200 rpm for 17 to 20 hours.
- a miniprep kit (Wizard® plus SV Minipreps DNA Purification System, Plasmids were prepared using Promega). The prepared plasmid was subjected to sequence confirmation using a Life Technologies 3730 DNA Analyzer sequencer.
- IPTG Isopropyl- ⁇ -D ( ⁇ )-thiogalactopyroside
- E. coli was collected by centrifugation, and suspended by adding 1/10 volume of 50 mM Tris-HCl buffer (pH 8) to the culture solution. Thereafter, using an ultrasonic crusher BioRuptorUCD-200T (manufactured by Cosmo Bio), a 30-second crushing-30-second pause process was repeated 10 cycles to obtain a crude extract of genetically engineered E.
- the gene recombinant E. coli disruption supernatant is packed in an ion exchange column HiTrap Q HP (manufactured by GE Healthcare) equilibrated with 50 mM Tris-HCl buffer (pH 8.0), and the medium-high pressure liquid chromatography system AKTA design ( GE Healthcare) was used to fractionate proteins with a 50 mM Tris-HCl buffer (pH 8.0) containing 1 M NaCl with a concentration gradient of 0 to 50%.
- the fractions having cellobiohydrolase activity were mixed together and then mixed into 50 mM Tris-HCl buffer (pH 8.0) containing 750 mM ammonium sulfate using a centrifugal ultrafiltration membrane VIVASPIN 20 (manufactured by Sartorius Stedim). The solution was changed.
- the cellobiohydrolase activity fraction after the solution exchange is packed in a hydrophobic interaction separation column HiTrap Phenyl HP (GE Healthcare) equilibrated with the same solution, and loaded in 50 mM Tris-HCl buffer (pH 8.0). Proteins were fractionated with a concentration gradient of 100-0%.
- the fractions having cellobiohydrolase activity were mixed together and then concentrated using VIVASPIN 20 until the liquid volume reached about 8 mL.
- the concentrated sample is added to a gel filtration column Hiload26 / 60 superdex200 pg (manufactured by GE Healthcare) equilibrated with 50 mM Tris-HCl buffer (pH 8.0) containing 150 mM NaCl, and the column volume is changed to 1-1. Fractionation was performed by flowing 5 volumes of the same buffer at a flow rate of 2 to 3 mL / min.
- the fractions having cellobiohydrolase activity were mixed together and then exchanged with a 50 mM Tris-HCl buffer (pH 8.0) and concentrated to obtain a purified enzyme having a final concentration of about 1 mg / mL.
- the recombinant E. coli disrupted supernatant and purified cellobiohydrolase enzyme protein were confirmed by SDS-PAGE analysis and Western blotting.
- SDS electrophoresis of the recombinant E. coli disrupted supernatant and the purified enzyme was performed using 4-20% mini-gradient gel and 10% mini-gel (manufactured by ATTO), respectively.
- the supernatant and purified enzyme were mixed with Tris-SDS ⁇ ME treatment solution (COSMO BIO INC.) At a ratio of 1: 1 and then treated at 100 ° C. for 10 minutes. Respectively migrated 0.5 ⁇ L.
- the immobilized gel was stained with Coomassie Brilliant Blue R250 (Merck) to visualize the protein band.
- the Western blotting of the recombinant E. coli disrupted supernatant and the purified enzyme was performed by SDS electrophoresis using a 10% mini gel (manufactured by ATTO), and then using a transfer device Trans-Blot SD (manufactured by Bio-Rad). Transferred to a vinylidene chloride film (manufactured by ATTO). The protein on the membrane was reacted with a rabbit primary antibody diluted 1000 times.
- the rabbit primary antibody is synthesized by synthesizing a polypeptide consisting of 20 amino acid residues (CDPNGSQSRYNSAYPTGALPN) at positions 384 to 403 encoded by AR19G-166-QV, and affinity-purifying the serum obtained by immunizing the rabbit. Prepared (manufactured by Operon Biotechnology). Detection of the primary antibody bound to the protein was performed using a Fast Western Blotting kit (Pierce), and an chemiluminescence signal was detected using an imaging device Ez-Capture MG (ATTO).
- CDPNGSQSRYNSAYPTGALPN 20 amino acid residues
- FIG. 4 shows the results of SDS-PAGE analysis (FIG. 4 (A)) and Western blot analysis (FIG. 4 (B)) of enzyme proteins obtained by expressing AR19G-166-RA and AR19G-166-QV in E. coli. Results are shown.
- Lane 1 is protein molecular weight index
- lanes 2 and 3 are AR19G-166-RA and AR19G-166-QV recombinant E. coli disrupted supernatants
- lanes 4 and 5 are purified AR19G-166-RA protein and It is an electrophoresis pattern of AR19G-166-QV protein.
- the cellobiohydrolase gene is generally very poorly expressed. For example, when the cellobiohydrolase gene is expressed using Escherichia coli as a host, the gene is hardly expressed regardless of whether it is derived from a filamentous fungus or a bacterium.
- the PCR clones AR19G-166-RA and AR19G-166-QV were both well expressed in E. coli.
- SDS-PAGE analysis of AR19G-166-RA and AR19G-166-QV recombinant E. coli disrupted supernatant a strong band was observed at a molecular weight of 46.7 kDa predicted from the amino acid sequence (SEQ ID NOs: 1 and 3). (Lanes 2 and 3 in FIG.
- AR19G-166-RA and AR19G-166-QV showed single bands corresponding to the above bands (lanes 4 and 5 in FIG. 4A).
- the recombinant recombinant Escherichia coli disrupted supernatant (lanes 2 and 3 in FIG. 4 (B)) and purified enzyme (FIG. 4) were obtained by Western blotting using an antibody against a polypeptide consisting of 20 amino acid residues at positions 384 to 403 of AR19G-166. In both lanes 4 and 5) of 4 (B), a single band of enzyme protein was detected at 46.7 kDa.
- PSA hydrolysis activity For measurement of cellobiohydrolase activity, phosphate swollen Avicel (PSA) was used as a substrate. PSA was prepared by once dissolving Avicel powder (microcrystalline cellulose powder, manufactured by Merck) with a phosphoric acid solution, adding sterilized distilled water to precipitate, and then washing until pH reached 5 or more. All the PSA used in the subsequent experiments were prepared by this method. The activity of the recombinant E.
- coli disrupted supernatant or the enzyme sample during purification was measured by 50 ⁇ L of 1 mM PSA-containing 200 mM acetate buffer (pH 5.5) and 50 ⁇ L of the recombinant E. coli disrupted supernatant or the enzyme during purification.
- the mixed solution consisting of the sample was reacted at 30 to 100 ° C. for 20 minutes.
- a mixed solution in which 50 mM Tris-HCl buffer (pH 8.0) was added instead of the recombinant E. coli disrupted supernatant and reacted under the same conditions was used as a control group.
- the substrate solution and the enzyme were separately kept at the reaction temperature for 5 minutes and then mixed to start the reaction.
- any of the mixed solutions was stirred using an Eppendorf thermomixer (1400 rpm).
- an equal volume of 3,5-dinitrosalicyclic acid reagent (DNS solution) was added, heat-treated at 100 ° C. for 5 minutes, and centrifuged after cooling for 5 minutes to obtain a supernatant.
- the amount of reducing sugar in the supernatant is measured by measuring the absorbance at 540 nm using a spectrophotometer, calculated using a calibration curve prepared with glucose, and the amount of reducing sugar produced by hydrolysis of the enzyme from the difference from the control section Asked.
- the enzyme activity for producing 1 ⁇ mol of reducing sugar per minute was defined as 1 U, and the value divided by the amount of protein was defined as the specific activity (U / mg).
- Substrate specificity of cellobiohydrolase The hydrolysis activity of various cellulose substrates and hemicellulose substrates was examined for AR19G-166-RA and AR19G-166-QV, which were confirmed to have PSA hydrolysis activity.
- the purified enzyme obtained in ⁇ 9> (final concentration of about 1 mg / mL) was used.
- the substrate specificity of cellobiohydrolase AR19G-166 is as follows: PSA, Avicel powder, CMC (carboxymethylcellulose, Sigma), xylan (derived from beech material, Sigma), lichenan (MP Biomedicals), laminarin (Laminaria) Measured using digital data (manufactured by Sigma).
- AR19G-166-RA and AR19G-166-QV showed high hydrolysis activity against water-soluble PSA. It also showed degradation activity against Richenan composed of ⁇ -1,3 bond and ⁇ -1,4 bond glucan and Avicel of crystalline cellulose.
- CMC Laminarin consisting of ⁇ -1,3 bond and ⁇ -1,6 bond glucan, and xylan showed almost no degradation activity.
- the enzyme substrate specificity of being very weak but having hydrolytic activity against crystalline cellulose Avicel and not degrading against xylan is that AR19G-166-RA and AR19G-166-QV are GH6 family It is a cellobiohydrolase belonging to the above.
- the hydrolysis reaction product was centrifuged at 12,000 rpm for 10 minutes at 4 ° C., and the supernatant was filtered through a filter having a pore size of 0.2 ⁇ m and subjected to HPLC analysis.
- the HPLC apparatus used was Alliance e2695 (manufactured by Waters), and an RI detector (2414RI) was used for sugar detection. Empor version 3.0 was used as the control and analysis software for the HPLC apparatus.
- the column was HPLC Carbohydrate Analysis Column 300 mm ⁇ 7.8 mm (manufactured by BIO-RAD), and the solvent was ultrapure water.
- a hydrolysis sample of 10 ⁇ L was analyzed at a flow rate of 0.6 mL / min and a column temperature of 85 ° C.
- a calibration curve was prepared using standard substances (glucose, cellobiose, cellotriose), and saccharides were quantified.
- the maximum concentration of the calibration curve sample was 0.2% by mass for glucose, 0.4% by mass for cellobiose, and 0.5% by mass for cellotriose.
- a dilution series was prepared to create a calibration curve with 6 points.
- the measurement results of the component analysis by HPLC are shown in FIGS.
- the product of PSA hydrolysis by AR19G-166-RA is mainly cellobiose (86.5%) and a small amount of cellotriose (13.5%) after 1 hour, and cellobiose 86.2% after 24 hours. And 13.0% of cellotriose and a very small amount of glucose (0.7%) (FIG. 5A).
- the PSA hydrolysis reaction products by TrCBHII are mainly cellobiose (87.5%) and a small amount of cellotriose (12.5%). After 24 hours, cellobiose is 88.4% and cellotriose is 9.4%. There was a very small amount of glucose (2.2%) (FIG. 5B).
- the results of this HPLC analysis also indicated that AR19G-166 is a cellobiohydrolase.
- FIGS. 6A and B are diagrams showing the results of measuring the PSA hydrolysis activity at each temperature with the horizontal axis as the temperature.
- FIGS. 7A and 7B show the PSA hydrolysis activity at each pH with the horizontal axis as the pH. It is the figure which showed the result.
- the measured value of the mixed solution of the substrate, the buffer and the enzyme was plotted.
- the purified enzyme AR19G-166-RA showed high PSA hydrolysis activity in the temperature range of 60-80 ° C. (FIG. 6A).
- the optimum temperature (T opt ) showing the highest activity was 70 ° C. at pH 4.5 and 75 ° C. at pH 5.0 to 6.0.
- the PSA hydrolysis activity of the purified enzyme AR19G-166-RA decreased sharply in any pH range.
- purified enzyme AR19G-166-QV had a lower PSA hydrolysis activity than AR19G-166-RA at 65 ° C. or higher (FIG. 6B).
- the optimum temperature (T opt ) showing the highest activity was 70 ° C. from pH 4.5 to pH 5.5 and 75 ° C. at pH 6.0. In any pH range, the PSA hydrolysis activity of the purified enzyme AR19G-166-RA rapidly decreased when the enzyme reaction temperature was 80 ° C. or higher.
- purified AR19G-166-RA showed the highest PSA hydrolysis activity in the reaction temperature range of 65 to 80 ° C. and pH of 4 to 6 (FIG. 7A).
- the optimum pH varies depending on the reaction temperature, pH 4.6 (actual value) at 60 to 65 ° C., pH 5.2 to 5.3 (actual value) at 70 to 75 ° C., and pH 5.8 at 80 ° C. (Actual measurement value).
- pH 4.6 actual value
- pH 5.2 to 5.3 actual value
- pH 5.8 pH 5.8 at 80 ° C.
- the purified enzyme AR19G-166-QV like AR19G-166-RA, exhibits the highest PSA hydrolysis activity in the pH range of 4 to 6, and in the pH ranges of 3.2 to 4.5 and pH 7 to 8, A low level of PSA hydrolysis activity was observed (FIG. 7B).
- the pre-incubation of the purified enzyme was carried out using a mixed solution (pH 5.0) consisting of 10 ⁇ L of purified enzyme, 40 ⁇ L of purified water, and 50 ⁇ L of 200 mM acetate buffer at 0, 20, 40, 60, 120, Incubated for 240, 480, 960 or 1440 minutes.
- PSA hydrolysis activity was measured except that the pre-incubation mixture and 1% by mass PSA aqueous solution were separately heated at 50 ° C. for 5 minutes, and then 100 ⁇ L of PSA aqueous solution was added to the mixture and reacted for 20 minutes.
- PSA hydrolysis activity U / mg
- Enzyme activity was shown as a relative value (relative activity,%) with the activity in the untreated section (no preincubation) as 100%.
- the pre-incubation time during which the enzyme activity was reduced to 50% of the untreated group was defined as the half-life T half .
- Purified AR19G-166-RA did not lose its PSA hydrolysis activity within the measurement time when the preincubation temperature was 50 to 60 ° C., and the half-life T half was 24 hours or more, the upper limit of measurement.
- the half-life T half was calculated to be 226 minutes by the approximate curve by the exponential function shown by the thick line in FIG. 8A.
- divalent metal ions stabilize protein structure and improve heat resistance by binding to protein.
- Calcium (Ca 2+ ), manganese (Mn 2+ ), cobalt (Co 2+ ), barium (Ba 2+ ), magnesium (Mg 2+ ), nickel (Ni 2+ ), divalent iron (Fe 2+ ), trivalent iron (Fe 3+) ), Zinc (Zn 2+ ) divalent metal ions (concentration: 1 mM) were administered into the enzyme-substrate (PSA) reaction solution, and the effect of the enzyme protein on the PSA hydrolysis activity was measured.
- PSA enzyme-substrate
- AR19G-166-RA and AR19G-166-QV enzyme activities increased at a final concentration of 1 mM calcium ion or cobalt ion at 85 ° C. or higher, and manganese ion enzyme activity in a temperature range of 60-90 ° C. Markedly increased (not shown).
- Other divalent metal ions had no effect (Ba 2+ , Mg 2+ , Ni 2+ ) or rather reduced enzyme activity (Fe 2+ , Fe 3+ , Zn 2+ ).
- thermo degradation temperature T m thermal degradation temperature of enzyme protein
- T m heat denaturation temperature
- T m heat decay temperature
- Preincubation temperature which the enzyme activity by a preliminary heating (pre-incubation) for a predetermined time is reduced to 50% of the untreated group is equal to the thermal degradation temperature T m of a protein, as indicated by the broken line drop line in FIG. 9A, the enzyme activity Can be obtained by measuring This method was determined thermal degradation temperature T m of a AR19G-166-RA and AR19G-166-QV.
- Example 2 Except for the reaction, the procedure was carried out in the same manner as in ⁇ 10> of Example 1, the amount of reducing sugar produced by the hydrolysis of the enzyme was determined, and the PSA hydrolysis activity (U / mg) was calculated. The PSA hydrolysis activity value of the enzyme was measured three times for each pre-incubation temperature, and the average value and standard error were determined. Data were normalized by setting the average values of the hydrolysis activity in the low temperature region (40 to 65 ° C.) and the high temperature region (90 to 100 ° C.) where the hydrolysis activity is saturated to 1 and 0, respectively.
- T m AR19G-166-RA Value of T m AR19G-166-RA is 76.4 ° C., whereas, value of T m AR19G-166-QV are 68.5 ° C., more of AR19G-166-RA is AR19G-166-QV than T m value Was about 8 ° C higher.
- administration of manganese ions at a concentration of 1 mM increased the thermal decay temperatures T m of AR19G-166-RA and AR19G-166-QV by 3.0 ° C. and 4.1 ° C., respectively.
- Example 2 When an arbitrary gene is introduced using a eukaryotic organism such as a filamentous fungus or a plant as a host, the optimum temperature of the expressed protein generally increases by about 5 to 10 ° C. This is due to a post-translational modification reaction in which a saccharide is added to a protein, called glycosylation (glycosylation modification), and the glycosylated protein becomes stable against heat.
- AR19G-166 gene was introduced into Aspergillus oryzae, a filamentous fungus, and the effect of sugar chain modification on the heat resistance of the encoded enzyme protein was verified.
- the PSA hydrolysis activity of the purified enzymes AR19G-166-RW and AR19G-166-QW expressed in E. coli was the same as that of ⁇ 10> of Example 1 in that the enzyme activity for producing 1 ⁇ mol of reducing sugar per minute was 1 U. And the value divided by the amount of protein, specific activity (U / mg) was calculated.
- the PSA hydrolyzing activity of AR19G-166-RW and AR19G-166-QW produced by Aspergillus transformants is the amount of reducing sugar at 100 ° C. at which AR19G-166-RW showed the maximum hydrolytic activity.
- the relative activity value (%) was calculated as%.
- FIG. 11A shows the relative activity value (%) of the calculated PSA hydrolysis activity at each temperature.
- FIG. 11A shows AR19G-166-RW and AR19G-166-QW expressed in E. coli as measured in ⁇ 13> of Example 1 (in the figure, “RW by E. coli” and “QW by E. coli, respectively).
- the measurement results of PSA hydrolyzing activity (U / mg) are also shown.
- the optimum temperatures (T opt ) of AR19G-166-RW and AR19G-166-QW expressed in E. coli were 80 ° C. and 75 ° C., respectively.
- the optimum temperatures of AR19G-166-RW and AR19G-166-QW expressed in Aspergillus oryzae (“RW by A. oryzae” and “QW by A. oryzae” in the figure, respectively) are both 100 ° C. or higher. Met.
- the AR19G-166 gene has an increase in molecular weight of about 10% by expressing Aspergillus oryzae and the optimum temperature increases by 20 to 30 ° C.
- AR19G-166 expressed by Aspergillus oryzae has an optimum temperature higher by 30 ° C. or more than cellobiohydrolase derived from a conventional thermophilic filamentous fungus and has excellent heat resistance.
- thermostable cellobiohydrolase that exhibits high enzyme activity even at 80 to 100 ° C. together with other thermostable cellulases, saccharification treatment of lignocellulose can be performed under high temperature conditions of 80 ° C. or higher.
- PSA hydrolysis activity U / mg was calculated.
- AR19G-166-RW and AR19G-166-QW produced by Aspergillus transformants were subjected to a PSA hydrolysis reaction at a temperature of 80 ° C., and the PSA hydrolysis activity at each pH was adjusted to pH 5.2 where the maximum activity was obtained.
- the relative activity value (%) was calculated with the PSA hydrolyzing activity of 100%.
- FIG. 11B shows the relative activity value (%) of the calculated PSA hydrolysis activity at each pH.
- FIG. 11B shows AR19G-166-RW and AR19G-166-QW expressed in E. coli measured in ⁇ 13> of Example 1 (in the figure, “RW by E. coli” and “QW by E. coli, respectively). The measurement results of PSA hydrolyzing activity (U / mg) are also shown.
- AR19G-166 enzymes expressed in Aspergillus oryzae (“RW by A. oryzae” and “QW by A. oryzae” in the figure) are AR19G-166 enzymes expressed in E. coli ("RW by E. coli” and in the figure).
- the pH was wider than that of “QW by E. coli”), and the pH showing 50% activity at the maximum value was in the range of 3.3 to 8.0 at a reaction temperature of 80 ° C. On the other hand, when E. coli was expressed, this pH range was 4.5 to 6.
- Example 3 In general, protein production of a recombinant gene using a plant as a host yields a much higher expression level than bacterial expression systems such as Escherichia coli or Bacillus and filamentous fungi expression systems such as Aspergillus oryzae.
- bacterial expression systems such as Escherichia coli or Bacillus and filamentous fungi expression systems such as Aspergillus oryzae.
- a chloroplast transformant accumulates 5 to 10% by mass of a foreign protein in a transformed leaf in a total soluble protein (TSP) ratio, and sometimes shows a high accumulation of a TSP ratio of 40% by mass or more.
- TSP total soluble protein
- a foreign protein is accumulated in a transformant tissue at a TSP ratio of about 1% by mass.
- tobacco chloroplast transformants were prepared by inserting AR19G-166-RA and AR19G-166-QV into the tobacco chloroplast genome.
- tobacco chloroplast transformation cassette vectors pNtaGL and pNtaGLPL having the structure shown in FIG. 12A were prepared.
- This vector is a vector for introducing a target gene by homologous recombination into a trnI gene-trnA gene region in an inverted repeat sequence in a tobacco chloroplast genome.
- the vector has an aadA (aminoglucoside 3′-adenyltransferase) gene expression cassette as a selection marker using spectinomycin resistance as an index, and the target gene expression cassette introduction site (ClaI-BsiWI) downstream of the aadA gene expression cassette. Part).
- the pNtaGL vector has a promoter (Prrn) of tobacco-derived 16S ribosomal RNA gene inserted as an expression control region of the aadA gene, but the pNtaGLPL vector does not contain a promoter region, and the expression of the aadA gene is a homologous recombination region. Depends on the upstream endogenous promoter.
- FIG. 12B shows expression cassettes pPXT and pPXTPPL of the target gene. Both are designed to insert the target gene into the BamHI site, and have only the Prrn promoter and the gene10 (T7g10) sequence derived from bacteriophage T7 or the T7g10 sequence on the 5 'side of the target gene, respectively.
- the T7g10 sequence is a sequence that has been suggested to be effective for high accumulation of foreign proteins in chloroplast expression of foreign genes.
- the 3′-UTR (TrbcL) of the tobacco chloroplast rbcL gene is commonly placed on the 3 ′ side of the target gene, both of which are chloroplast transformations shown in FIG. 12A by the ClaI site and BsiWI site at both ends of the cassette. It can be introduced into the cassette vector pNtaGL or pNtaGLPL vector.
- PCR clones AR19G-166-RA and AR19G-166-QV were each amplified with a primer with a BamHI linker, and the obtained amplification products were inserted into the BamHI site of the expression cassette pPXT or pPXTPPL.
- the expression cassette pPXT into which AR19G-166-QV has been inserted into pNtaGL using the ClaI site and the BsiWI site, the aadA gene expression cassette and the AR19G-166-QV expression cassette are located in the trnI gene-trnA gene region.
- a chloroplast transformation construct pNtaGL-QV having a structure linked in tandem was prepared.
- FIG. 12C schematically shows the structures of the chloroplast transformation constructs pNtaGL-QV and pNtaGLPL-RA.
- QV means AR19G-166-QV
- RA means AR19G-166-RA.
- Tobacco chloroplast transformation was basically performed according to the method of Daniell et al. (Daniell® et al., “Methods in Molecular Molecular Biology,” 2005, “Vol. 286,” p. 111-138). Specifically, tobacco aseptically seeded and grown in MS plate medium (Murashige and Skog (MS) medium (pH 5.8) containing 30 g / L sucrose solidified with 3 g / L gellan gum) Cut green leaves of Nicotiana tabacum cv.SR-1 to 0.5 cm square, and RMOP medium (Sbav et al., Proc. Natl. Acad. Sci. USA, 1990, Vol. 87, p.
- the particle gun used 0.6 ⁇ m gold particles and a 1100 psi rupture disc, and the distance from the rupture disc to the sample was about 9 cm.
- Tobacco leaves after introduction of the gene construct are cultured in the dark at 25 ° C. for 3 days, then transplanted to an RMOP medium containing 500 mg / L of spectinomycin, and treated at 25 ° C. for 16 hours in the light period / 8 hours in the dark period. Planted every week. In the middle, the regenerated shoot leaves were cut, transplanted to an RMOP medium containing 500 mg / L spectinomycin, and repeatedly dedifferentiated and shoot redifferentiated to repeat homoplasmic of the plant body in a heteroplasmic state. Promoted.
- the BglII-digested DNA was subjected to Southern blotting using a probe having the same base sequence as the trnI upstream region of about 1 kb, and the probe was chemiluminescently detected by AlkPhos Direct from GE Healthcare. Theoretically, the probe provides approximately 4.5 kb for wild-type tobacco, 7.1 kb for pNtaGL-QV and pNtaGLPL-RA chloroplast-transformed tobacco, and 6 chloroplast-transformed tobacco for pNtaGL or pNtaGLPL vectors, respectively. A 0.0 kb or 5.9 kb DNA fragment is detected.
- FIGS. 13A and 13B Two lines of chloroplast-transformed tobacco (QV-2, QV-17) obtained by introduction of pNtaGL-QV and three lines of chloroplast-transformed tobacco (RA-6) obtained by introduction of pNtaGLPL-RA -2-1, RA-6-2-2, RA-6-2-3)
- RA-6 chloroplast-transformed tobacco
- FIGS. 13A and 13B The results of Southern hybridization are shown in FIGS. 13A and 13B.
- FIG. 13C shows the result of Southern hybridization of chloroplast-transformed tobacco obtained by introducing the pNtaGL and pNtaGLPL vectors.
- FIG. 14A is a photograph of flowering of AR19G-166-QV introduced chloroplast transformed tobacco plants (T 1 generation) and vector control (PNtaGL),
- FIG. 14B is likewise AR19G-166-RA (T 1 Generation) and vector control (pNtaGLPL) flowering period.
- the frozen leaf pieces were crushed for 90 seconds at 30 Hz using a mixer mill MM400 (manufactured by Lecce), and then 50 mM acetic acid containing 1 volume% protease inhibitor (manufactured by Sigma) 10 times the weight of the leaf pieces.
- a suspension to which buffer (pH 5.5) was added was prepared.
- the suspension was sufficiently stirred and then centrifuged to prepare a soluble protein extract containing enzyme proteins (AR19G-166-QV and AR19G-166-RA).
- AR19G-166-RA the extract was concentrated 5 to 10 times with a centrifugal ultrafiltration membrane VIVASPIN 20 (manufactured by Sartorius Stedim).
- a soluble protein extract was prepared from pNtaGL or pNtaGLPL vector-introduced chloroplast-transformed tobacco plants by the same treatment.
- the soluble protein extract was confirmed by SDS-PAGE analysis and Western blot analysis.
- SDS electrophoresis and Western blotting were performed using a mini-PROTEAN TGX stain free gel (Bio-Rad).
- the extract and purified enzyme were mixed with Tris-SDS ⁇ -ME treatment solution (COSMO BIO INC.) At 1: 1, followed by treatment at 100 ° C. for 10 minutes.
- AR19G-166-QV was 5 ⁇ L per sample, AR19G. -166-RA and control individuals were electrophoresed at 10 ⁇ L, and purified enzyme at 0.2 ⁇ g.
- Western blotting was performed in the same manner as ⁇ 9> in Example 1.
- FIG. 15A to 15D show SDS-PAGE analysis of extracts of soluble proteins obtained from chloroplast-transformed tobacco plants introduced with AR19G-166-QV and chloroplast-transformed tobacco plants introduced with pNtaGL.
- FIG. 15A shows SDS-PAGE analysis of extracts of soluble proteins obtained from chloroplast-transformed tobacco plants introduced with AR19G-166-QV and chloroplast-transformed tobacco plants introduced with pNtaGL.
- FIG. 15B Western blot analysis
- FIG. 15C The results of SDS-PAGE analysis
- FIG. 15D Western blot analysis of the extract of FIG.
- lane 1 is a protein molecular weight index
- lane 2 is a purified enzyme protein
- lanes 3 to 5 are chloroplast traits into which three AR19G-166-QV or AR19G-166-RA were introduced.
- Soluble protein extracts obtained from converted tobacco plants, and lanes 6 to 8 are soluble protein extracts obtained from chloroplast-transformed tobacco plants into which three individuals pNtaGL or pNtaGLPL have been introduced.
- Both AR19G-166-QV and AR19G-166-RA enzyme proteins were expressed in tobacco chloroplasts.
- SDS-PAGE analysis of soluble protein extracts from chloroplast-transformed tobacco plants of AR19G-166-QV and AR19G-166-RA corresponding to each purified enzyme protein (lane 2 in FIGS. 15A and 15C) A band was observed at the position (lanes 3 to 5 in FIGS. 15A and 15C).
- no band was observed in the control individuals into which pNtaGL or pNtaGLPL was introduced (lanes 6 to 8 in FIGS. 15A and 15C).
- AR19G-166-QV lanes 3 to 5 in FIG. 15B
- AR19G-166-RA FIG.
- FIGS. 16A and 16B The PSA hydrolysis activity of AR19G-166-QV protein and AR19G-166-RA protein expressed with tobacco chloroplasts at each temperature is shown in FIGS. 16A and 16B.
- the enzyme activity is represented by the amount of reducing sugar in the temperature range of 30 ° C. to 100 ° C.
- AR19G-166-QV and AR19G-166-RA expressed with tobacco chloroplasts showed the same temperature dependence of PSA hydrolysis activity as AR19G-166-QV and AR19G-166-RA expressed with E. coli. And confirmed to function normally.
- AR19G-166-QV expressed in tobacco chloroplasts FIGS. 16A and 16B.
- Example 4 When an arbitrary gene is introduced using a eukaryotic organism such as a filamentous fungus or a plant as a host, the optimum temperature of the expressed protein generally increases by about 5 to 10 ° C. This is due to a post-translational modification reaction in which a saccharide is added to a protein, called glycosylation (glycosylation modification), and the glycosylated protein becomes stable against heat.
- glycosylation glycosylation modification
- AR19G-166-RA and AR19G-166-QV genes were introduced into Arabidopsis thaliana, a cruciferous plant, and the effect of sugar chain modification on the heat resistance of the encoded enzyme protein was verified.
- the obtained culture broth was applied to an LB agar medium containing 50 mg / L kanamycin and 10 mg / L PPT (phosphinotricin), and left to stand for 2 days in an incubator at 28 ° C. to transform transformed agro Obtained bacteria.
- the plasmid was extracted and the sequence was confirmed using a 3730 DNA Analyzer sequencer (manufactured by Life Technologies).
- a transformed Agrobacterium cultivated using an Arabidopsis thaliana plant grown at 22 ° C. for 24 hours in the light period and an LB medium containing 50 mg / L kanamycin and 10 mg / L PPT.
- lane 1 is a protein molecular weight index
- lane 2 is a crude enzyme extract of AR19G-166-RA transgenic Arabidopsis (Arabi_RA4) leaves
- lane 3 is AR19G-166-QV transgenic Arabidopsis (Arabi_QV4).
- Leaf crude enzyme extract, lane 4 is a wild-type Arabidopsis (WT) leaf crude enzyme extract.
- the crude enzyme extracts of the Arabidopsis transformant introduced with AR19G-166-RA (Arabi_RA4) and the Arabidopsis transformant introduced with AR19G-166-QV (Arabi_QV4) have strong bands at 53.9 kDa and 52.1 kDa, respectively. Appeared.
- the molecular weight of the enzyme protein of the transformant Arabi_RA4 is slightly larger than that of the transformant Arabi_QV4 (lanes 2 and 3 in FIG. 17). When the protein is produced in E. coli, the size is 46.7 kDa.
- the protein encoded by the AR19G-166-RA gene and the AR19G-166-QV gene expressed using Arabidopsis as the host has an apparent molecular weight of They increased by 7.2 kDa and 5.4 kDa, respectively. This increase in molecular weight is due to sugar chain addition, and the difference in the molecular weight of the expressed enzyme protein between the transformants Arabi_RA4 and Arabi_QV4 is considered to be due to the difference in the degree of sugar chain addition.
- the AR19G-166-RA enzyme protein expressed using Arabidopsis as the host is estimated to have a temperature at which the highest enzyme activity is 100 ° C., the upper limit of measurement, and an optimum temperature of 100 ° C. or higher.
- the optimum temperature of AR19G-166-QV enzyme protein was 90 ° C.
- the AR19G-166 gene is expressed in the Arabidopsis thaliana nuclear genome system, the molecular weight increases by about 10%, and the optimum temperature increases by 15 to 30 ° C.
- Arabidopsis thaliana expressed AR19G-166-RA is extremely excellent in heat resistance, and the optimum temperature is higher by 30 ° C. or more than conventional thermostable cellobiohydrolase derived from thermophilic filamentous fungi.
- thermostable cellobiohydrolase according to the present invention is expressed by a nuclear genome expression system of a eukaryote such as a plant or a filamentous fungus, and has high cellobiohydrolase activity even at 80 ° C. or higher. It is clear that an enzyme can be obtained.
- the super thermostable cellobiohydrolase of the present invention showing high enzyme activity in the temperature range of 80 to 100 ° C. together with endoglucanase, xylanase, ⁇ -glucosidase, etc., which are also highly thermostable, lignocellulose It is possible to perform the saccharification treatment at a high temperature of 80 ° C.
- Streptomyces genus bacteria that are actinomycetes are known to produce useful antibiotics and physiologically active substances, and are useful bacteria widely used industrially.
- a large-scale expression system for foreign genes using the substance-producing ability has been developed, and several successful examples have been reported (Patent Documents 3, 4, and 5, Non-Patent Documents 9, 10, and 11).
- actinomycetes have a genome with a high GC content, the expression of genes with a high GC content, which is difficult to express in E. coli, tends to be good (Non-patent Document 11), and the expression of heterologous proteins is cell-free extract of actinomycetes.
- Non-patent Document 9 An extremely high level of expression up to 40% is also reported (Non-patent Document 9). As a means for mass-producing the thermostable cellobiohydrolase according to the present invention at lower cost, the expression of the protein in actinomycetes into which the AR19G-166-RA gene was introduced was verified.
- Lane 1 in FIG. 19 is a protein molecular weight index
- lane 2 is an E. coli-expressed AR19G-166-RA purified protein (arrow)
- lane 3 is an cell-free extract of AR19G-166-RA transgenic actinomycetes Streptomides lividans. It is.
- strong expression of the target protein was confirmed at the expected size (46.7 kDa) (lane 3 in FIG. 19).
- any of the mixed solutions was stirred using an Eppendorf thermomixer (1400 rpm).
- 50 ⁇ L of 1% by weight phosphate-swelled Avicel (PSA) -containing 200 mM acetate buffer (pH 5.5) was reacted at each temperature, and after stopping the reaction, 50 ⁇ L of a cell-free extract sample was added.
- PSA phosphate-swelled Avicel
- a cell-free extract sample was added.
- an equal volume of 3,5-dinitrosalicyclic acid reagent (DNS solution) was added, heat-treated at 100 ° C. for 5 minutes, and centrifuged after cooling for 5 minutes to obtain a supernatant.
- the absorbance at 540 nm of the supernatant was measured using a spectrophotometer, the amount of reducing sugar in the supernatant was calculated using a calibration curve prepared with glucose, and generated by hydrolysis of the enzyme from the difference from the control group The amount of reducing sugar was determined. Each measurement was performed by three independent trials, and an average value and a standard error were obtained. The result is shown in FIG. In FIG. 20, each data point was measured three times, and the average value and standard error were plotted against temperature.
- the specific activity at 80 ° C. was 3.02 when the enzyme activity for producing 1 ⁇ mol of reducing sugar per minute was defined as 1 U, and the value divided by the amount of enzyme protein was defined as the specific activity (U / mg).
- the AR19G-166-RA cellobiohydrolase enzyme showed good expression and activity in actinomycetes, it was revealed that it can be used as a gene transfer host of the present invention.
- CBM cellulose binding function
- CBM carbhydrate-binding module
- the function of CBM is to adsorb to an insoluble substrate to increase the concentration of the catalytic domain associated with the CBM around the substrate to improve the degradation rate of cellulose, or to separate hydrogen bonds between cellulose chains by CBM binding. It is known that the crystal structure is destroyed (Non-patent Documents 12 and 13).
- Non-Patent Document 14 there is a report that the affinity and the resolution to crystalline cellulose are increased by adding CBM to a kind of endoglucanase which does not originally have CBM.
- thermostable cellobiohydrolase As a means for further enhancing the cellulolytic activity of the thermostable cellobiohydrolase according to the present invention, a gene in which CBM is added to AR19G-166-RA is prepared, and CBM addition to the cellulolytic activity of the encoded enzyme protein is carried out. The effect was verified.
- the added linker and the amino acid sequence of the CBM3 gene are shown in SEQ ID NO: 17, the nucleotide sequence is shown in SEQ ID NO: 18, and the amino acid sequence of the entire CBM-added AR19G-166-RA gene optimized for the codon usage of E. coli is shown in SEQ ID NO: 19.
- the base sequence is represented by SEQ ID NO: 20, respectively.
- the 3-base TAA at positions 808 to 810 of SEQ ID NO: 18 and the 3-base TAA at positions 2092 to 2094 of SEQ ID NO: 20 are both stop codons.
- the gene synthesized as described above was incorporated into Expression Vector pLEAD (manufactured by NIPPON GENE), transformed with JM109 strain, and the sequence was confirmed using Life Technologies 3730 DNA Analyzer sequencer.
- E. coli crude extract A part of the crude E. coli extract was electrophoresed by SDS-PAGE to confirm the expression of the target protein at the expected size. After confirming the expression of the protein, Escherichia coli solution cultured overnight at 37 ° C. was used as a preculture solution, and main culture was carried out in an LB medium containing 100 times the amount of 100 mg / L ampicillin.
- the gene recombinant E. coli disruption supernatant is packed in an ion exchange column HiTrap Q HP (manufactured by GE Healthcare) equilibrated with 50 mM Tris-HCl buffer (pH 8.0), and the medium-high pressure liquid chromatography system AKTA design ( GE Healthcare) was used to fractionate proteins with a 50 mM Tris-HCl buffer (pH 8.0) containing 1 M NaCl with a concentration gradient of 0 to 50%.
- the fractions having cellobiohydrolase activity were mixed together, and then subjected to solution exchange and concentration to 1 mM phosphate buffer (pH 6.8) using a centrifugal ultrafiltration membrane VIVASPIN 20 (manufactured by Sartorius Stedim). And loaded onto a hydroxyapatite column CHT5-1 (BioRad) equilibrated with the same buffer, and the protein was fractionated with a 400 mM phosphate buffer (pH 6.8) with a concentration gradient of 0 to 100%. The fractions having cellobiohydrolase activity were mixed together and then concentrated using VIVASPIN 20 until the liquid volume reached about 8 mL.
- the concentrated sample is added to a gel filtration column Hiload26 / 60 superdex200 pg (manufactured by GE Healthcare) equilibrated with 50 mM Tris-HCl buffer (pH 8.0) containing 150 mM NaCl, and the column volume is changed to 1-1. Fractionation was performed by flowing 5 volumes of the same buffer at a flow rate of 2 to 3 mL / min. Fractions with cellobiohydrolase activity were mixed together, then exchanged and concentrated to 50 mM phosphate buffer (pH 6) with VIVASPIN 20, and ion exchange column HiTrap SP HP equilibrated with the same solution.
- lane 1 is a protein molecular weight index
- lane 2 is a recombinant E. coli crushed supernatant
- lane 3 is purified CBM-added AR19G-166-RA protein
- lane 4 is Example 1. It is an electrophoresis pattern of the cellobiohydrolase enzyme protein refine
- CBM-added AR19G-166-RA protein was expressed in E. coli.
- SDS-PAGE analysis of the recombinant E. coli disrupted supernatant a band was observed around the molecular weight of 74.5 kDa predicted from the amino acid sequence (SEQ ID NO: 19) (lane 2 in FIG. 21A).
- SEQ ID NO: 19 amino acid sequence predicted from the amino acid sequence (SEQ ID NO: 19)
- thermostable cellobiohydrolase according to the present invention has cellobiohydrolase activity at least at 75 ° C. and pH 5.5, and is suitable for saccharification treatment of cellulose-containing biomass under high temperature conditions of 75 ° C. or higher.
- the thermostable cellobiohydrolase and the polynucleotide used for the production thereof, the expression vector incorporating the polynucleotide, and the transformant into which the expression vector is introduced include, for example, energy from cellulose-containing biomass. It can be used in the field of production.
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Abstract
Description
本願は、2013年3月27日に国際出願された国際出願番号PCT/JP2013/059028に基づき優先権を主張し、その内容をここに援用する。
[1]本発明の第一の態様は、
(A)配列番号1で表されるアミノ酸配列からなるポリペプチド、
(B)配列番号1で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(C)配列番号1で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(D)配列番号3で表されるアミノ酸配列からなるポリペプチド、
(E)配列番号3で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(F)配列番号3で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(G)配列番号5で表されるアミノ酸配列からなるポリペプチド、
(H)配列番号5で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(I)配列番号5で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(J)配列番号7で表されるアミノ酸配列からなるポリペプチド、
(K)配列番号7で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、又は
(L)配列番号7で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
からなるセロビオハイドロラーゼ触媒領域を有する、耐熱性セロビオハイドロラーゼである。
[2]前記[1]の耐熱性セロビオハイドロラーゼとしては、さらに、セルロース結合モジュールを有することが好ましい。
[3]本発明の第二の態様は、
(a)配列番号1で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(b)配列番号1で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(c)配列番号1で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(d)配列番号3で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(e)配列番号3で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(f)配列番号3で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(g)配列番号5で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(h)配列番号5で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(i)配列番号5で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(j)配列番号7で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(k)配列番号7で表されるアミノ酸配列のうちの1若しくは数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(l)配列番号7で表されるアミノ酸配列と80%以上の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(m)配列番号2、4、6、又は8で表される塩基配列と80%以上の配列同一性を有し、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、又は
(n)配列番号2、4、6、又は8で表される塩基配列からなるポリヌクレオチドとストリンジェントな条件でハイブリダイズするポリヌクレオチドの塩基配列であり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
からなるセロビオハイドロラーゼ触媒領域をコードする領域を有する、ポリヌクレオチドである。
[4]前記[3]のポリヌクレオチドとしては、さらに、セルロース結合モジュールをコードする領域を有することが好ましい。
[5]本発明の第三の態様は、前記[3]又は[4]のポリヌクレオチドが組込まれており、宿主細胞において、少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドを発現し得る、発現ベクターである。
[6]本発明の第四の態様は、前記[5]の発現ベクターが導入されている形質転換体である。
[7]前記[6]の形質転換体は、真核微生物であることが好ましい。
[8]前記[6]の形質転換体は、植物であることが好ましい。
[9]本発明の第五の態様は、前記[6]~[8]のいずれかの形質転換体内で、耐熱性セロビオハイドロラーゼを生産する、耐熱性セロビオハイドロラーゼの製造方法である。
[10]本発明の第六の態様は、前記[1]の耐熱性セロビオハイドロラーゼ、前記[2]の耐熱性セロビオハイドロラーゼ、又は前記[9]の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼと、少なくとも1種以上のその他のセルラーゼを含む、セルラーゼ混合物である。
[11]前記[10]のセルラーゼ混合物において、前記その他のセルラーゼはヘミセルラーゼ及びエンドグルカナーゼからなる群より選択される1種以上であることが好ましい。
[12]本発明の第七の態様は、セルロースを含む材料を、前記[1]の耐熱性セロビオハイドロラーゼ、前記[2]の耐熱性セロビオハイドロラーゼ、前記[6]~[8]のいずれかの形質転換体、又は前記[9]の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼに接触させることによりセルロース分解物を生産する、セルロース分解物の製造方法である。
[13]前記[12]のセルロース分解物の製造方法において、前記セルロースを含む材料に、さらに少なくとも1種以上のその他のセルラーゼを接触させることが好ましい。
[14]前記[13]のセルロース分解物の製造方法において、前記その他のセルラーゼは、ヘミセルラーゼ及びエンドグルカナーゼからなる群より選択される1種以上であることが好ましい。
[15]本発明の第八の態様は、生物由来のDNA又は生物由来のRNAの逆転写産物を鋳型として、配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは数個の塩基が付加された塩基配列からなるフォワードプライマーと、配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは数個の塩基が付加された塩基配列からなるリバースプライマーと、を用いてPCRを行い、増幅産物として、耐熱性セロビオハイドロラーゼをコードする塩基配列を含むポリヌクレオチドを得る、耐熱性セロビオハイドロラーゼをコードするポリヌクレオチドの製造方法である。
[16]本発明の第九の態様は、配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは数個の塩基が付加された塩基配列からなるプライマーである。
[17]本発明の第十の態様は、配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは数個の塩基が付加された塩基配列からなるプライマーである。
〔1〕(A)配列番号1で表されるアミノ酸配列からなるポリペプチド、
(B)配列番号1で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(C)配列番号1で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(D)配列番号3で表されるアミノ酸配列からなるポリペプチド、
(E)配列番号3で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(F)配列番号3で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(G)配列番号5で表されるアミノ酸配列からなるポリペプチド、
(H)配列番号5で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(I)配列番号5で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(J)配列番号7で表されるアミノ酸配列からなるポリペプチド、
(K)配列番号7で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、又は
(L)配列番号7で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
からなるセロビオハイドロラーゼ触媒領域を有する、耐熱性セロビオハイドロラーゼ、
〔2〕さらに、セルロース結合モジュールを有する、〔1〕に記載の耐熱性セロビオハイドロラーゼ、
〔3〕(a)配列番号1で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(b)配列番号1で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(c)配列番号1で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(d)配列番号3で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(e)配列番号3で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(f)配列番号3で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(g)配列番号5で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(h)配列番号5で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(i)配列番号5で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(j)配列番号7で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(k)配列番号7で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(l)配列番号7で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(m)配列番号2、4、6、又は8で表される塩基配列と80%以上100%未満の配列同一性を有し、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、又は
(n)配列番号2、4、6、又は8で表される塩基配列からなるポリヌクレオチドとストリンジェントな条件でハイブリダイズするポリヌクレオチドの塩基配列であり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
からなるセロビオハイドロラーゼ触媒領域をコードする領域を有する、ポリヌクレオチド、
〔4〕さらに、セルロース結合モジュールをコードする領域を有する、〔3〕に記載のポリヌクレオチド、
〔5〕〔3〕又は〔4〕に記載のポリヌクレオチドが組込まれており、
宿主細胞において、少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドを発現し得る、発現ベクター、
〔6〕〔5〕に記載の発現ベクターが導入されている、形質転換体、
〔7〕原核生物である、〔6〕に記載の形質転換体、
〔8〕真核生物である、〔6〕に記載の形質転換体、
〔9〕植物である、〔6〕に記載の形質転換体、
〔10〕〔6〕~〔9〕のいずれか一項に記載の形質転換体内で、耐熱性セロビオハイドロラーゼを生産する、耐熱性セロビオハイドロラーゼの製造方法、
〔11〕〔1〕に記載の耐熱性セロビオハイドロラーゼ、〔2〕に記載の耐熱性セロビオハイドロラーゼ、又は〔10〕に記載の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼと、少なくとも1種のその他のセルラーゼを含む、セルラーゼ混合物、
〔12〕前記その他のセルラーゼが、ヘミセルラーゼ及びエンドグルカナーゼからなる群より選択される1種以上のセルラーゼである、〔11〕に記載のセルラーゼ混合物、
〔13〕セルロースを含む材料を、〔1〕に記載の耐熱性セロビオハイドロラーゼ、〔2〕に記載の耐熱性セロビオハイドロラーゼ、〔6〕~〔9〕のいずれか一項に記載の形質転換体、又は〔10〕に記載の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼに接触させることにより、セルロース分解物を生産する、セルロース分解物の製造方法、
〔14〕前記セルロースを含む材料に、さらに少なくとも1種のその他のセルラーゼを接触させる、〔13〕に記載のセルロース分解物の製造方法、
〔15〕前記その他のセルラーゼが、ヘミセルラーゼ及びエンドグルカナーゼからなる群より選択される1種以上のセルラーゼである、〔14〕に記載のセルロース分解物の製造方法、
〔16〕生物由来のDNA又は生物由来のRNAの逆転写産物を鋳型として、配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるフォワードプライマーと、配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるリバースプライマーと、を用いてPCRを行い、増幅産物として、耐熱性セロビオハイドロラーゼをコードする塩基配列を含むポリヌクレオチドを得る、耐熱性セロビオハイドロラーゼをコードするポリヌクレオチドの製造方法、
〔17〕配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるプライマー、及び
〔18〕配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるプライマー。
また、本発明に係るポリヌクレオチド、当該ポリヌクレオチドが組込まれた発現ベクター、当該発現ベクターが導入されている形質転換体は、本発明に係る耐熱性セロビオハイドロラーゼの製造に好適に用いられる。
糸状菌、細菌、アーキアを含む多くの微生物は難培養性であり、土壌など微生物環境に生息する菌の99%が未知の菌であるといわれている。特に、高温環境に生息する微生物の培養は極めて困難であり、現在の微生物培養技術では土壌中に生息する微生物の0.1%以下を単離・培養しているにすぎないと考えられている。この高温土壌微生物の難培養性が、耐熱性セロビオハイドロラーゼの開発が進まない一因である。
本発明及び本願明細書において「少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド」とは、前記ポリペプチドを含有する溶液のpHが5.5の時に75℃で最も高いセロビオハイドロラーゼ活性を有することを意味する。すなわち、前記ポリペプチドを含有する溶液がpH5.5以外、かつ75℃以外の条件下でセロビオハイドロラーゼ活性を有していなくとも、前記溶液をpH5.5かつ75℃の条件にした時に前記溶液がセロビオハイドロラーゼ活性を有していれば、前記ポリペプチドは本発明の範囲に含まれる。
本発明及び本願明細書において「耐熱性セロビオハイドロラーゼ」とは、55~80℃、pH3.5~7.0で前記セロビオハイドロラーゼ活性を有する酵素が好ましく、70~100℃、pH4.0~6.0で前記セロビオハイドロラーゼ活性を有する酵素がより好ましい。
(A)配列番号1で表されるアミノ酸配列からなるポリペプチド。
(B)配列番号1で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(C)配列番号1で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(D)配列番号3で表されるアミノ酸配列からなるポリペプチド。
(E)配列番号3で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(F)配列番号3で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(G)配列番号5で表されるアミノ酸配列からなるポリペプチド。
(H)配列番号5で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(I)配列番号5で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(J)配列番号7で表されるアミノ酸配列からなるポリペプチド。
(K)配列番号7で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
(L)配列番号7で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド。
本発明及び本願明細書において、「ポリペプチドにおいてアミノ酸が置換する」とは、ポリペプチドを構成しているアミノ酸が別のアミノ酸に変わることを意味する。
本発明及び本願明細書において、「ポリペプチドにおいてアミノ酸が付加される」とは、ポリペプチド中に新たなアミノ酸が挿入されることを意味する。
本発明の第二の態様であるポリヌクレオチドは、本発明の第一の態様である耐熱性セロビオハイドロラーゼをコードする。当該耐熱性セロビオハイドロラーゼは、当該ポリヌクレオチドが組込まれた発現ベクターを宿主に導入することにより、当該宿主の発現系を利用して生産することができる。
(a)配列番号1で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列。
(b)配列番号1で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(c)配列番号1で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(d)配列番号3で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列。
(e)配列番号3で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(f)配列番号3で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(g)配列番号5で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列。
(h)配列番号5で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(i)配列番号5で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(j)配列番号7で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列。
(k)配列番号7で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(l)配列番号7で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(m)配列番号2、4、6、又は8で表される塩基配列と80%以上100%未満の配列同一性を有し、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
(n)配列番号2、4、6、又は8で表される塩基配列からなるポリヌクレオチドとストリンジェントな条件でハイブリダイズするポリヌクレオチドの塩基配列であり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列。
本願及び本願明細書において、「ポリヌクレオチドにおいて塩基が欠失する」とは、ポリヌクレオチドを構成しているヌクレオチドの一部が失われる(除去される)ことを意味する。
本発明及び本願明細書において、「ポリヌクレオチドにおいて塩基が置換する」とは、ポリヌクレオチドを構成している塩基が別の塩基に変わることを意味する。
本発明及び本願明細書において、「ポリヌクレオチドにおいて塩基が付加される」とは、ポリヌクレオチド中に新たな塩基が挿入されることを意味する。
前記(b)、(c)、(e)、(f)、(h)、(i)、(k)、(l)、又は(m)の塩基配列からなるポリヌクレオチドを人工的に合成する際に、配列番号2、4、6、又は8で表される塩基配列に対して欠失、置換若しくは付加される塩基の数は、合成後のポリヌクレオチドの塩基配列が配列番号2、4、6、又は8で表される塩基配列と80%以上100%未満の配列同一性を有していれば特に限定されないが、1~256個が好ましく、1~192個がより好ましく、1~128個がさらに好ましく、1~64個が特に好ましい。
本発明の第三の態様である発現ベクターは、前記本発明の第二の態様のポリヌクレオチドが組込まれており、宿主細胞において、少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドを発現し得る。すなわち、前記本発明の第二の態様のポリヌクレオチドが、前記本発明の第一の態様の耐熱性セロビオハイドロラーゼを発現し得る状態で組込まれた発現ベクターである。
本発明及び本願明細書において、発現ベクターとは、上流から、プロモーター配列を有するDNA、外来DNAを組込むための配列を有するDNA、及びターミネーター配列を有するDNAを含むベクターである。
具体的には、上流から、プロモーター配列を有するDNA、前記本発明の第二の態様のポリヌクレオチド、ターミネーター配列を有するDNAからなる発現カセットとして発現ベクターに組込まれていることが必要である。なお、ポリヌクレオチドの発現ベクターへの組込みは、周知の遺伝子組み換え技術を用いることにより行うことができ、市販の発現ベクター作製キットを用いてもよい。
本発明の第四の態様である形質転換体は、前記本発明の第三の態様の発現ベクターが導入されている。当該形質転換体中では、前記本発明の第一の態様の耐熱性セロビオハイドロラーゼを発現させ得る。従来公知のセロビオハイドロラーゼは、現宿主のレンジが狭い、つまり、異種発現が難しいものが多い。これに対して、本発明に係る耐熱性セロビオハイドロラーゼは、大腸菌、放線菌、酵母、糸状菌、高等植物葉緑体等、広範な発現宿主に発現させることができる。
本発明に係る耐熱性セロビオハイドロラーゼを発現させるための宿主細胞としては、大腸菌、酵母、糸状菌、放線菌、及び植物からなる群より選択される少なくとも1の宿主細胞が好ましく、酵母、糸状菌、放線菌、及び植物からなる群より選択される少なくとも1の宿主細胞がより好ましく、植物がさらに好ましい。
本発明に係る形質転換体が植物である場合、これらの中でも単子葉植物が好ましく、イネ科植物がより好ましく、バイオマス量の多いイネ科植物がさらに好ましい。
本発明の第五の態様である耐熱性セロビオハイドロラーゼの製造方法は、前記本発明の第四の態様の形質転換体内で、耐熱性セロビオハイドロラーゼを生産する方法である。前記本発明の第二の態様のポリヌクレオチドが、発現の時期等の制御能を有していないプロモーターの下流に組込まれている発現ベクターを用いて製造された形質転換体内では、本発明に係る耐熱性セロビオハイドロラーゼが恒常的に発現している。一方で、特定の化合物や温度条件等によって発現を誘導するいわゆる発現誘導型プロモーターを用いて製造された形質転換体に対しては、それぞれの発現誘導条件に適した誘導処理を行うことにより、当該形質転換体内に耐熱性セロビオハイドロラーゼを発現させる。
すなわち、本発明の耐熱性セロビオハイドロラーゼの製造方法は、本発明の第四の態様の形質転換体内で耐熱性セロビオハイドロラーゼを発現させること、及び所望により前記形質転換体から前記耐熱性セロビオハイドロラーゼを抽出し精製することを含む。
本発明の第六の態様であるセルラーゼ混合物は、前記本発明の第一の態様の耐熱性セロビオハイドロラーゼ、又は前記第五の態様の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼと、少なくとも1種のその他のセルラーゼを含む。前記第五の態様の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼは、形質転換体内に含まれた状態のものであってもよく、形質転換体から抽出・精製されたものであってもよい。本発明に係る耐熱性セロビオハイドロラーゼを、その他のセルラーゼとの混合物としてセルロースの分解反応に用いることにより、難分解性であるリグノセルロースをより効率よく分解させることができる。
本発明の第七の態様であるセルロース分解物の製造方法は、本発明に係る耐熱性セロビオハイドロラーゼにより、セルロースを分解して分解物を得る方法である。具体的には、セルロースを含む材料を、前記本発明の第一の態様の耐熱性セロビオハイドロラーゼ、前記本発明の第四の態様の形質転換体、又は前記第五の態様の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼに接触させることにより、セルロース分解物を生産する。
本発明及び本願明細書における「セルロース分解物」とは、セロビオースを含む。
本発明の第八の態様である耐熱性セロビオハイドロラーゼをコードするポリヌクレオチドの製造方法は、生物由来のDNA又は生物由来のRNAの逆転写産物を鋳型として、配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるフォワードプライマー(本発明の第九の態様であるプライマー)と、配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるリバースプライマー(本発明の第十の態様であるプライマー)とを用いてPCRを行い、増幅産物として、耐熱性セロビオハイドロラーゼをコードする塩基配列を含むポリヌクレオチドを得る方法である。
<1> 温泉土壌からのDNA抽出と全ゲノムシーケンス(Whole Genome Sequence、WGS)
耐熱性セロビオハイドロラーゼ(至適温度:55℃以上)、超耐熱性セロビオハイドロラーゼ(至適温度:80℃以上)の遺伝子探索を目的として、中性~弱アルカリ性温泉から土壌DNAを採取し、これらの土壌を構成する微生物叢メタゲノムDNAの塩基配列解読を行った。
中性~弱アルカリ性温泉土壌サンプルとして、野外にて高温の温泉が噴き出している日本国内の3ヶ所、5地点(メタゲノムDNAサンプルN2、AR19、AR15、OJ1、及びH1)から、土壌、泥、バイオマットを含む温泉水を採取した。これらの温泉土壌サンプルは、採取時の温度58~78℃、pH7.2~8のレンジにあった。
各温泉土壌サンプル当たり3~4回、計19回、メタゲノムDNAの配列解読を行い、平均リード長394bp、総リード数26,295,463、総ゲノム解読量10.3Gbpの全ゲノムシーケンス(WGS)データセットを得た。
温泉メタゲノムから抽出したゲノムDNAを使い、Roche社製 454 GS FLX Titanium technologyショットガンシーケンス用の標準プロトコールに従って、シーケンスライブラリーを構築した。Roche 454の出力(sffファイル)をPyroBayes(Quinlan et al., Nature Methods, 2008, vol.5, p.179-81.)にて再ベースコールし、FASTA形式の配列ファイル及びQuality値ファイルを取得した。得られたシーケンスリードは、端を切り落とし品質を上げ、454 Life SciencesのアセンブルソフトウェアNewbler version 2.3又は2.5.3を使ってアセンブルした。アセンブルは、「minimum acceptable overlap match (mi)=0.9」、「option:-large(for large or complex genomes,speeds up assembly,but reduces accuracy.)」に設定して行った。
Qualityフィルター処理したリードと100bp以上のアセンブルコンティグは、合計2.5Gbpあり、このデータセットをセルラーゼ酵素遺伝子解析に用いた。リード総数26,294,193リードのうち17,991,567リードが、平均で1kb以上のコンティグにアセンブルされ(計595,602コンティグ)、このうち最大コンティグ長は278,185bpであった。
UniProtデータベース(http://www.uniprot.org/)からEC番号が3.2.1.4(セルロース)、3.2.1.37(β-キシロシダーゼ)、3.2.1.91(セルロース 1,4-β-セロビオシダーゼ)、3.2.1.8(エンド1,4-β-キシラナーゼ)の配列をダウンロードし(アクセス日:2009/4/13)、これらグリコシド加水分解酵素遺伝子のプロテオームローカルデータベースを構築した。メタゲノムAR15及びAR19ではアノテーションソフトウェアOrphelia(Hoff et al., Nucleic Acids Research, 2009, 37 (Web Server issue: W101-W105)を使用し、メタゲノムH1、N2、OJ1ではMetagene(Noguchi et al., DNA Research, 2008,15 (6))を使用して、前記<2>で得たコンティグ配列から、遺伝子領域(=オープンリーディングフレーム)を推定した(Orphelia option:default(model=Net700,maxoverlap=60)、Metagene option:-m)。推定されたORFからグリコシド加水分解酵素遺伝子を抽出するために、BLASTP(blastall ver.2.2.18)を使い、ローカルデータベースに参照した。BLASTPのoption条件は、「Filter query sequence=false」、「Expectation value(E)<1e-20」[以下、デフォルト値:Cost to open a gap=-1、Cost to extended gap=-1、X dropoff value for gapped alignment=0、Threshold for extending hits=0、Word size=default]とし、ヒットした配列をグリコシド加水分解酵素遺伝子として収集した。
アノテーションソフトウェアOrpheliaは、ATG(メチオニン)の他、レアコドンのGTG(バリン)、TTG(ロイシン)、及びATA(イソロイシン)を開始コドンとしてORF検出する。このため、アセンブルされたコンティグにATGを開始コドンとする完全長ORFが含まれない場合、Orpheliaはレアコドンを開始コドンとして認識するエラーが発生する。前記<3>においてOrpheliaにより完全長と出力されたORFのうち、レアコドンGTG、TTG、ATAを開始コドンとするORFは8個あった。genewiseによるORF出力とORFが含まれるコンティグのアミノ酸配列を参照し、これらのORFがレアコドンを開始コドンとする完全長配列か、あるいは、出力エラーであるか、確認を行った。その結果、Orpheliaが出力したレアコドンを開始コドンとする8個のORFは、全て出力エラーであること、すなわち不完全長配列であることが判明した。
オープンリーディングフレームOJ1-1は、548アミノ酸からなり、セルロース結合モジュールCBM3(149bp)-リンカー(111bp)-GH6触媒領域を持つマルチドメイン酵素をコードしていた。但し、触媒領域の後半部は終止コドンが欠落し、不完全長であった。また、このセルロース結合モジュール配列は、好熱性好気性細菌Caldibacillus cellulovoransのセロビオハイドロラーゼ(Genbank:AAF22273.1)が有するセルロース結合モジュールCBM3(配列番号16)とアミノ酸配列で63%の配列同一性を示す新規なCBM3配列である。OJ1-1のセロビオハイドロラーゼ触媒領域は、Amycolatopsis mediterranei U32のセルロース1,4-β-セロビオシダーゼ(Genbank:ADJ46954.1)とアミノ酸配列で58%の配列同一性を示し、強力なセルラーゼ酵素を有している好熱性放線菌Thermobifida fusca YXのβ-1,4-セロビオハイドロラーゼ(Genbank:AAA62211.1)とアミノ酸配列で48%の配列同一性を示した。
オープンリーディングフレームAR19G-166は、474アミノ酸からなるポリペプチド(配列番号9)をコードしていたが、開始コドンが失われている不完全長配列であって、リンカーの部分配列とGH6触媒領域だけから構成されていた。AR19G-166のGH6触媒領域は、クロロフレクサス門中温性好気性細菌Herpetosiphon aurantiacus DSM 785のグルコシドハイドロラーゼ(Genbank:ABX04776.1)と66%のアミノ酸配列同一性を示した。配列番号14で表される塩基配列からなるフォワードプライマー(5’-CACCATGTTGGACAATCCATTCATCGGAG-3’:配列番号12で表される塩基配列の5’末端側に7塩基(CACCATG)付加したもの。当該付加配列中、3’側のATGは開始コドンであり、5’側のCACCはベクターに挿入するための配列である。)と配列番号13で表される塩基配列からなるリバースプライマー(5’-TTAGGGTTGGATCGGCGGATAG-3’)を用いたPCRクローニングにより、AR19G-166から2個の遺伝子クローン(AR19G-166-RAとAR19G-166-QV)が得られた。AR19G-166-RAとAR19G-166-QVは、299位と351位の2アミノ酸のみが相違していた。AR19G-166-RAは、299位のアミノ酸がアルギニンであり、351位のアミノ酸がアラニンであった(配列番号1)。AR19G-166-QVは、299位のアミノ酸がグルタミンであり、351位のアミノ酸がバリンであった(配列番号3)。
培養分離された菌体からクローニングされた遺伝子とは違い、メタゲノム解析によりクローニングされた遺伝子の由来は不明である。高温土壌メタゲノムから得られたGH6ファミリーに属する4個のオープンリーディングフレーム(AR19G-166、AR19G-12(OJ1-2)、OJ1-1)が、バクテリアやアーキア(古細菌)など原核生物に由来するのか、あるいは、糸状菌やキノコなど真核生物に由来するのか、わからない。そこで、触媒領域アミノ酸配列のマルチプルアライメントと分子系統樹による系統遺伝学解析を行い、これらオープンリーディングフレームの由来を推定した。
糸状菌ファミリー6グルコシドハイドロラーゼ:Acremonium cellulolyticus Y-94 cellobiohydrolase II(Genbank:BAA74458.1); Agaricus bisporus cellobiohydrolase(Genbank:AAA50608.1); Aspergillus kawachii IFO 4308 1,4-beta-D-glucan cellobiohydrolase C(Genbank:GAA89571.1); Aspergillus niger ATCC 1015 1,4-beta-D-glucan cellobiohydrolase C(Genbank:EHA25828.1); Chaetomium thermophilum cellobiohydrolase family 6(Genbank:AAW64927.1); Colletotrichum higginsianum glucoside hydrolase family 6(Genbank:CCF33252.1); Fomitiporia mediterranea MF3/22 cellulase CEL6B(Genbank:EJD02201.1);Glomerella graminicola M1.001 glucosyl hydrolase family 6(Genbank:EFQ25807.1); Humicola insolens Cel6A (PDB:1BVW); Leptosphaeria maculans JN3 cellobiohydrolase II(EMBL-Bank:CBX97039.1); Magnaporthe grisea 70-15 exoglucanase 2(Genbank:EHA57773.1); Myceliophthora thermophila ATCC 42464 glucoside hydrolase family 6 (Genbank:AEO55787.1); Neurospora crassa OR74A exoglucanase 2(Genbank:EAA31534.1); Penicillium decumbens cellobiohydrolase II(Genbank:ADX86895.1); Punctularia strigosozonata HHB-11173 SS5 cellobiohydrolase II(Genbank:EIN07098.1); Talaromyces emersonii cellobiohydrolase II(Genbank:AAL33604.4); Thielavia terrestris NRRL 8126 glucoside hydrolase family 6(Genbank:AEO62210.1); Trichoderma reesei cellobiohydrolase II(Genbank:AAA34210.1); Verticillium dahliae VdLs.17 exoglucanase-6A (Genbank:EGY16046.1)。
バクテリアファミリー6グルコシドハイドロラーゼ:Acidothermus cellulolyticus 11B glucoside hydrolase family 6(Genbank:ABK52388.1); Amycolatopsis mediterranei U32 1,4-beta-cellobiosidase (Genbank:ADJ46954.1); Cellulomonas fimi ATCC 484 1,4-beta-cellobiohydrolase(Genbank:AEE46055.1); Cellvibrio japonicus Ueda 107 cellobiohydrolase cel6A(Genbank:ACE85978.1); Herpetosiphon aurantiacus DSM 785 glucoside hydrolase family 6(Genbank:ABX04776.1); Jonesia denitrificans DSM 20603 glucoside hydrolase family 6(Genbank:ACV08399.1); Ktedonobacter racemifer DSM 44963 1,4-beta-cellobiohydrolase(Genbank:EFH85864.1); Micromonospora lupini str. Lupac 08 1,4-beta-cellobiohydrolase(Genbank:CCH20969.1); Paenibacillus curdlanolyticus YK9 1,4-beta-cellobiohydrolase(Genbank:EFM08880.1); Ralstonia solanacearum Po82 cellobiohydrolase A(Genbank:AEG71050.1); Salinispora arenicola CNS-205 glucoside hydrolase family 6(Genbank:ABV99773.1); Stackebrandtia nassauensis DSM 44728 1,4-beta-cellobiosidase(Genbank:ADD42622.1); Stigmatella aurantiaca DW4/3-1 exoglucanase A(Genbank:EAU67050.1); Streptomyces avermitilis MA-4680 1,4-beta-cellobiosidase(Genbank:BAC69564.1); Teredinibacter turnerae T7901 cellobiohydrolase(Genbank:ACR12723.1); Thermobifida fusca YX cellobiohydrolase Cel6B(Genbank:AAA62211.1); Verrucosispora maris AB-18-032 1,4-beta-cellobiohydrolase(Genbank:AEB46944.1); Xanthomonas campestris pv. raphani 756C exoglucanase A(Genbank:AEL08359.1); Xanthomonas oryzae pv. oryzae KACC 10331 1,4-beta-cellobiosidase (Genbank:AAW77289.1); Xylanimonas cellulosilytica DSM 15894 glucoside hydrolase family 6(Genbank:ACZ30181.1); Xylella fastidiosa Ann-1 cellobiohydrolase A(Genbank:EGO81204.1)。
AR19G-166-RA及びAR19G-166-QVと高いアミノ酸配列同一性を示したHerpetosiphon aurantiacus DSM 785のファミリー6グルコシドハイドロラーゼは、1128アミノ酸から構成されている。当該遺伝子は、1位から29位までの29アミノ酸からなる移行シグナル配列から始まり、37位から136位までの100アミノ酸からなるセルロース結合モジュールCBM2、241位から611位までの370アミノ酸からなるGH6触媒領域、さらに、その下流に713位から1082位までの370アミノ酸からなるもう一つのGH6触媒領域から構成されるマルチドメイン遺伝子である。Pfamが示したこれらGH6触媒領域は、いずれも370アミノ酸残基から構成され、バクテリアGH6触媒領域、例えば、423アミノ酸残基から構成されるThermobifida fusca YX Cel6Bの触媒領域よりも50アミノ酸残基以上も短く、実際の触媒領域をカバーできていないと考えられた。そこで、BLASTPにより、Thermobifida fusca YX Cel6Bと相同なHerpetosiphon aurantiacus DSM 785のGH6触媒領域を検索したところ、図2Aにあるように、1番目のGH6触媒領域は230位のバリン(V)から657位のグルタミン(Q)までの428アミノ酸残基から構成されていた。
PCRクローニングにより得られたセロビオハイドロラーゼ候補遺伝子を、ゲノムDNA増幅キット(GenomiPhi V2 DNA Amplification Kit、GEヘルスケア社製)で増幅した温泉土壌DNAをテンプレートにして、PCRにより増幅した。増幅したPCR産物はChampion pET Directional TOPO(登録商標) Expression Kits(Invitrogen社製)のpET101/D-TOPOベクターに挿入し、One Shot TOP10株に形質転換した。コロニーPCRによりポジティブクローンを選抜し、100mg/Lアンピシリンを含むLB液体培地を用いて37℃、200rpmで17~20時間培養した後、ミニプレップキット(Wizard(登録商標) plus SV Minipreps DNA Purification System、Promega社製)を用いてプラスミドの調製を行った。調製したプラスミドは、ライフテクノロジーズ社の3730 DNA Analyzerシーケンサを用いて配列確認を行った。
シーケンス確認後、目的遺伝子をもつプラスミドを、ヒートショック法によりタンパク質発現用大腸菌へ導入した。形質転換用コンピテントセルは、ChampionTM pET Directional TOPO(登録商標) Expression Kits(Invitrogen社製)に付属のBL21 Star(DE3)株若しくはRosetta-gamiB(DE3)pLysS株(Merck社製)を用いた。目的の遺伝子をもつ大腸菌を、100mg/Lアンピシリンを含むLB培地に植菌し、OD600=0.2~0.8程度まで培養した後、IPTG(Isopropyl-β-D(-)-thiogalactopyranoside)を添加し、さらに5~20時間培養することによって、目的タンパク質の発現誘導を行った。培養後、遠心分離を行って大腸菌を回収し、培養液の1/10容量の50mM Tris-HClバッファー(pH8)を加えて懸濁した。その後、超音波破砕装置BioRuptorUCD-200T(コスモバイオ社製)を用いて、30秒間破砕-30秒間休止工程を10サイクル繰り返し、目的タンパク質を含む遺伝子組換え大腸菌の粗抽出物を得た。当該遺伝子組換え大腸菌粗抽出物をフィルター(孔径φ=0.45μm、ミリポア社製)で濾過し、得られた濾液を遺伝子組換え大腸菌破砕上清とした。
遺伝子組換え大腸菌破砕上清と精製酵素のSDS電気泳動は、それぞれ4-20%のミニグラジェントゲルと10%のミニゲル(ATTO社製)を用いて行った。前記上清及び精製酵素とTris-SDSβME処理液(コスモバイオ社製)を1:1で混合した後に100℃で10分間処理し、1サンプルあたり、遺伝子組換え大腸菌破砕上清は5μL、精製酵素は0.5μLをそれぞれ泳動させた。泳動終了後、固定化したゲルをクマシーブリリアントブルーR250(Merck社製)で染色し、タンパク質のバンドを可視化した。
遺伝子組換え大腸菌破砕上清と精製酵素のウェスタンブロッティングは、10%ミニゲル(ATTO社製)を用いてSDS電気泳動を行った後、転写装置Trans-Blot SD(バイオラッド社製)を用いてポリフッ化ビニリデン膜(ATTO社製)へ転写した。膜上のタンパク質は1000倍に希釈したウサギ1次抗体と反応させた。当該ウサギ1次抗体は、AR19G-166-QVがコードする384~403位の20アミノ酸残基(CDPNGQSRYNSAYPTGALPN)からなるポリペプチドを合成し、ウサギを免疫して得られた血清をアフィニティー精製することによって作製した(オペロンバイオテクノロジー社製)。タンパク質と結合した1次抗体の検出は、FastWestern Blotting kit(Pierce社製)を用いて行い、化学発光シグナルの検出には、イメージング装置Ez-Capture MG(ATTO社製)を使用した。
セロビオハイドロラーゼ活性測定には、リン酸膨潤アビセル(PSA)を基質として用いた。PSAはリン酸溶液でアビセル粉末(微結晶性セルロース粉末、Merck社製)を一旦溶解させた後に滅菌蒸留水を加えて析出させた後、pHが5以上になるまで洗浄することによって調製した。なお、以降の実験に用いたPSAは全て当該方法により調製した。
遺伝子組換え大腸菌破砕上清、又は精製途中の酵素試料の活性測定は、50μLの1質量%PSA含有200mM 酢酸バッファー(pH5.5)と50μLの遺伝子組換え大腸菌破砕上清、又は精製途中の酵素試料からなる混合液を、30~100℃で20分間反応させることにより行った。
全ての計測において、遺伝子組換え大腸菌破砕上清の代わりに50mM Tris-HClバッファー(pH8.0)を入れて同条件で反応させた混合液をコントロール区とした。また、基質溶液と酵素は、反応温度で5分間それぞれ別々に保温した後に混合し、反応開始とした。反応中、いずれの混合液も不溶性基質の沈殿を防ぐため、エッペンドルフ社のサーモミキサー(1400rpm)を用いて攪拌した。反応終了後は、等量の3,5-dinitrosalicylic acid reagent(DNS溶液)を加えて100℃で5分間加熱処理し、5分間の冷却後に遠心し、上清を得た。上清中の還元糖量を、分光光度計を用いて540nmの吸光度を計測し、グルコースで作成した検量線を用いて算出し、コントロール区との差分から酵素の加水分解によって生成した還元糖量を求めた。1分間に1μmolの還元糖を生成する酵素活性を1Uとし、タンパク質量で除した値を比活性(U/mg)とした。
PSA加水分解活性が確認されたAR19G-166-RA及びAR19G-166-QVに対して、様々なセルロース基質とヘミセルロース基質に対する加水分解活性を調べた。計測には、前記<9>で得られた精製酵素(終濃度約1mg/mL)を用いた。
セロビオハイドロラーゼAR19G-166の基質特異性は、PSA、アビセル粉末、CMC(カルボキシメチルセルロース、Sigma社製)、キシラン(ブナ材由来、Sigma社製)、リケナン(MP Biomedicals社製)、ラミナリン(Laminaria digitata由来、Sigma社製)を用いて計測した。具体的には、50μLの200mM 酢酸バッファー(pH5.5)と40μLの精製水と10μLの精製酵素からなる混合液を50℃で5分間プリインキュベーションした後、さらに100μLの各基質の1質量%水溶液を添加し、50℃で20分間(アビセル粉末を基質とした場合は2時間)反応させることにより行った。前記<10>と同様にして酵素の加水分解によって生成した還元糖量を求め、比活性(U/mg)を算出した。各計測は、3回の独立した試行により行い、平均値と標準偏差を求めた。さらに、PSAに対する比活性を100%とした場合の各基質に対する比活性の相対活性値(%)を算出した。結果を表2に示す。
リン酸膨潤アビセルPSAを基質とし、セロビオハイドロラーゼAR19G-166―RA及び木材腐朽糸状菌T.reeseiのファミリー6CBH(TrCBHII)による加水分解反応産物について、高速液体クロマトグラフィー(HPLC)による成分分析を行った。AR19G-166―RAでは0.1M酢酸バッファー(pH5.5)、70℃で、TrCBHIIでは0.1M酢酸バッファー(pH4.0)、40℃で、それぞれ1時間と24時間、PSAの加水分解反応を行った後、0.1M炭酸ナトリウム溶液の添加により反応を停止させた。加水分解反応産物を4℃、12,000rpmで10分間遠心分離し、上清を孔径0.2μmのフィルターでろ過し、HPLC分析に供試した。HPLC装置はAlliance e2695(Waters社製)を使用し、糖の検出にはRI検出器(2414RI)を用いた。HPLC装置の制御及び解析ソフトはEmpowerバージョン3.0を使用した。カラムはHPLC Carbohydrate Analysis Column 300mm×7.8mm(BIO-RAD社製)を用い、溶媒は超純水を使用した。流速0.6mL/min、カラム温度85℃で加水分解試料10μLを分析した。検量線は標準物質(グルコース、セロビオース、セロトリオース)を用いて作成し、糖類の定量を行った。検量線サンプルの最大濃度は、グルコースでは0.2質量%、セロビオースでは0.4質量%、セロトリオースでは0.5質量%であり、希釈系列を作成して6点で検量線を作成した。
AR19G-166-RA及びAR19G-166-QVによるPSA加水分解活性の温度依存性及びpH依存性及を調べた。計測には、前記<9>で得られた精製酵素(終濃度約1mg/mL)を用いた。
精製酵素のPSA加水分解活性の測定は、100μLの1質量%PSA水溶液と、50μLのマッキルベインバッファー(pH3~8)と、40μLの精製水と、10μLの精製酵素からなる混合液を、30、40、50、60、65、70、75、80、85、90、又は100℃で20分間反応させた以外は、実施例1の<10>と同様に行い、酵素の加水分解によって生成した還元糖量を求め、PSA加水分解活性(U/mg)を算出した。
計測結果を図6A及びB、並びに図7A及びBに示す。図6A及びBは、横軸を温度として、各温度におけるPSA加水分解活性を計測した結果を示した図であり、図7A及びBは、横軸をpHとして各pHにおけるPSA加水分解活性を計測した結果を示した図である。pHは、基質とバッファーと酵素の混合液の実測値をプロットした。
AR19G-166-RA及びAR19G-166-QVの熱安定性(耐熱性)を調べるため、20分間~1440分間プリインキュベーションを行い、各温度における酵素タンパク質のPSA加水分解活性を計測した。
測定には、前記<9>で得られた精製酵素(終濃度約1mg/mL)を用いた。精製酵素のプリインキュベーションは、精製酵素10μLと、精製水40μLと、200mM酢酸バッファー50μLからなる混合液(pH5.0)を、50~80℃の各温度で0、20、40、60、120、240、480、960、又は1440分間保温し、行った。PSA加水分解活性の測定は、プリインキュベーション後の混合液と1質量%PSA水溶液をそれぞれ別々に50℃で5分間加温した後、PSA水溶液100μLを前記混合液に加え、20分間反応させた以外は、実施例1の<10>と同様に行い、酵素の加水分解によって生成した還元糖量を求め、PSA加水分解活性(U/mg)を算出した。
精製AR19G-166-RAは、プリインキュベーション温度50~60℃の場合、計測時間内にPSA加水分解活性が失われることはなく、半減期Thalfは計測上限の24時間以上であった。70℃では、図8Aの太線で示した指数関数による近似曲線により半減期Thalfが226分と算出された。80℃では、プリインキュベーションにより酵素活性は直ちに失われた(図8A)。
一方、精製AR19G-166-QVの耐熱性はAR19G-166-RAと比べ、かなり低かった。プリインキュベーション温度50℃では、計測時間内にPSA加水分解活性はほとんど失われず、半減期Thalfは24時間以上であった。プリインキュベーション温度の上昇とともに酵素活性半減期Thalfは短くなり、60℃で16時間、70℃でさらに短くなり、40分であった。80℃では、酵素活性は直ちに失われた(図8B)。
一般に二価金属イオンは、タンパク質に結合することでタンパク質の構造を安定させ、耐熱性を向上させることが知られている。カルシウム(Ca2+)、マンガン(Mn2+)、コバルト(Co2+)、バリウム(Ba2+)、マグネシウム(Mg2+)、ニッケル(Ni2+)、二価鉄(Fe2+)、三価鉄(Fe3+)、亜鉛(Zn2+)の各二価金属イオン(濃度1mM)を酵素-基質(PSA)反応液中に投与し、酵素タンパク質のPSA加水分解活性に対する効果を計測した。まず、精製酵素液(濃度1mg/mL)10μL、精製水又は各二価金属の5mM塩化物水溶液40μL、200mM酢酸バッファー50μL(pH5.5)の混合液を、30℃で30分間プリインキュベーションした。PSA加水分解活性の測定は、プリインキュベーション後の混合液と1質量%PSA水溶液をそれぞれ別々に30~100℃の各温度で5分間加温した後、PSA水溶液100μLを前記混合液に加え、各温度で20分間反応させた以外は、実施例1の<10>と同様に行い、酵素の加水分解によって生成した還元糖量を求め、PSA加水分解活性(U/mg)を算出した。
タンパク質の熱安定性に関わるもう一つの指標は、熱変性温度又は熱崩壊温度Tm(melting temperature)である。一定時間の予備加温(プリインキュベーション)により酵素活性が無処理区の50%に減少するプリインキュベーション温度はタンパク質の熱崩壊温度Tmに等しく、図9Aの破線ドロップラインが示すように、酵素活性を計測することにより求めることができる。この方法により、AR19G-166-RA及びAR19G-166-QVの熱崩壊温度Tmを求めた。
糸状菌や植物など真核生物を宿主として任意の遺伝子を導入すると、発現したタンパク質は一般に至適温度が5~10℃程度上昇する。これは、グリコシル化(糖鎖修飾)と呼ばれる、タンパク質へ糖類が付加する翻訳後修飾反応によるものであり、グリコシル化されたタンパク質は熱に対し安定的になる。糸状菌であるコウジカビAspergillus oryzaeにAR19G-166遺伝子を導入し、コードする酵素タンパク質の耐熱性に対する糖鎖修飾の効果を検証した。
AR19G-166-RA及びAR19G-166-QVの351位アミノ酸残基をトリプトファン(W)に置換した変異体AR19G-166-RW(アミノ酸配列:配列番号5、塩基配列:配列番号6)及びAR19G-166-QW(アミノ酸配列:配列番号7、塩基配列:配列番号8)を作製し、これらを含む発現カセットをコウジカビに導入し、AR19G-166-RW又はAR19G-166-QWを発現するコウジカビ形質転換体を作製した。
こうして得られたコウジカビ形質転換体を培養した後、培養液上清を回収した。この培養上清を、遠心式の限外濾過膜VIVASPIN 20(Sartorius stedim社製)を用いて1/10容量への濃縮と50mM Tris-HClバッファー(pH8.0)への溶液交換を行い、これを濃縮上清とした。
実施例1の<8>と同様にして、変異体AR19G-166-RW及びAR19G-166-QWをpET101/D-TOPOベクターに挿入したプラスミドを作製した。実施例1の<9>と同様にして、これらのプラスミドをタンパク質発現用大腸菌へ導入した大腸菌形質転換体を作製し、得られた大腸菌形質転換体に対して発現誘導を行い、培養後、遠心分離を行って大腸菌を回収し、目的タンパク質を含む組換え大腸菌粗抽出物を得、これを濾過して大腸菌破砕上清を得た。実施例1の<9>と同様にして、イオン交換カラム、疎水性相互作用分離カラム、及びゲル濾過カラムによって分画、精製し、終濃度約1mg/mLの精製酵素を得た。
当該遺伝子組換えコウジカビ形質転換体及び当該遺伝子組換え大腸菌により生産されたAR19G-166-RW及びAR19G-166-QWのPSA加水分解活性の温度依存性を調べた。計測には、前記<2>で得られた濃縮上清及び<3>で得られた精製酵素を用いた。
各温度におけるPSA加水分解活性の計測は、前記<2>で得られた濃縮上清を用い、反応液のpHを5.5とした以外は、実施例1の<13>と同様に行い、酵素の加水分解によって生成した還元糖量を求めた。大腸菌発現させた精製酵素AR19G-166-RW及びAR19G-166-QWのPSA加水分解活性は、実施例1の<10>と同様にして、1分間に1μmolの還元糖を生成する酵素活性を1Uとし、タンパク質量で除した値、比活性(U/mg)を算出した。一方、コウジカビ形質転換体により生産されたAR19G-166-RW及びAR19G-166-QWのPSA加水分解活性は、AR19G-166-RWが最大加水分解活性を示した100℃での還元糖量を100%として、相対活性値(%)を算出した。
コウジカビ形質転換体及び大腸菌形質転換体により生産された、AR19G-166-RW及びAR19G-166-QWのPSA加水分解活性のpH依存性を調べた。計測には、前記<2>で得られた濃縮上清と、前記<3>で得られた精製酵素を用いた。
各pHにおけるPSA加水分解活性の計測は、前記<2>で得られた濃縮上清を用いた以外は、実施例1の<13>と同様に行い、酵素の加水分解によって生成した還元糖量を求めた。大腸菌形質転換体により生産されたAR19G-166-RW及びAR19G-166-QWは、それぞれ80℃と75℃でPSA加水分解反応を行い、PSA加水分解活性(U/mg)を算出した。コウジカビ形質転換体により生産されたAR19G-166-RW及びAR19G-166-QWでは、温度80℃でPSA加水分解反応を行い、各pHにおけるPSA加水分解活性を、最大活性が得られたpH5.2のPSA加水分解活性を100%とした相対活性値(%)として算出した。
一般的に、植物を宿主とする組換え遺伝子のタンパク質生産は、大腸菌、又はバチルス等の細菌発現系やコウジカビ等の糸状菌発現系と比べ、はるかに高い発現量が得られる。特に、葉緑体形質転換体は、形質転換葉中に外来タンパク質を全可溶性タンパク質(TSP)比で5~10質量%蓄積させ、時にはTSP比40質量%以上の高い蓄積を示すことがある。一方、核ゲノム形質転換は、形質転換体組織に外来タンパク質をTSP比1質量%程度蓄積する。このように、植物によるタンパク質生産、特に葉緑体形質転換体による外来タンパク質生産は、従来のタンパク質生産プラットフォームである細菌や糸状菌培養をはるかに凌ぐ経済メリットがある。そこで、AR19G-166-RA及びAR19G-166-QVをタバコ葉緑体ゲノム内に挿入したタバコ葉緑体形質転換体を作製した。
葉緑体形質転換コンストラクトを構成する葉緑体ゲノム内導入領域、5’/3’発現調節領域、及び選抜マーカー遺伝子等は、これまでに報告されている外来タンパク質の高発現例を参考に設計した(Daniell et al., Methods in Molecular Biology, 2005, Vol. 286, p. 111-138; Verma and Daniell, Plant Physiol., 2007, Vol. 145, p. 1129-1143)。
セロビオハイドロラーゼ酵素タンパク質の抽出は、AR19G-166-QVまたはAR19G-166-RA導入葉緑体形質転換タバコ植物体から各一系統を選出し、それぞれ別々の3個体から以下のように行った。開花期になった葉緑体形質転換タバコ植物体の中間部の葉3枚から、100mg前後の葉片を各5~10枚切り出した。各々の葉片は、予め直径3mmのタングステンビーズ(QIAGEN社製)を3個入れた2mLのサンプルチューブに入れ、その状態で液体窒素に投入し凍結させた。凍結した葉片に対し、ミキサーミル MM400(レッチェ社製)を用いて30Hzで90秒間の破砕を行った後、葉片重量の10倍容の1容量%のプロテアーゼインヒビター(Sigma社製)を含む50mM 酢酸バッファー(pH5.5)を加えた懸濁液を調製した。当該懸濁液を充分に撹拌した後に遠心分離を行うことにより、酵素タンパク質(AR19G-166-QV及びAR19G-166-RA)を含む可溶性タンパク質の抽出液を調製した。AR19G-166-RAについては、抽出液を遠心式の限外濾過膜VIVASPIN 20(Sartorius stedim社製)によって、5~10倍の濃縮を行った。また、比較解析用のコントロールとして、pNtaGLまたはpNtaGLPLベクター導入葉緑体形質転換タバコ植物体からも同様の処理によって、可溶性タンパク質の抽出液を調製した。
AR19G-166の384~403位の20アミノ酸残基からなるポリペプチドに対する抗体を用いたウェスタンブロットにより、AR19G-166-QV(図15Bのレーン3~5)及びAR19G-166-RA(図15Dのレーン3~5)の葉緑体形質転換タバコ植物体の可溶性タンパク質の抽出液の双方において、それぞれの精製酵素タンパク質(図15B、図15Dのレーン2)に対応する位置にバンドが認められた。また、AR19G-166-QV及びAR19G-166-RAにおいて、当該酵素タンパク質よりも分子量が小さい位置にもバンドが認められた。おそらくは、植物体内で酵素タンパク質の一部が消化された、あるいは発現が不十分な酵素タンパク質が混在していることが考えられる。一方、pNtaGL及びpNtaGLPLを導入したコントロール個体においては、バンドは全く認められなかった(図15B、図15Dのレーン6~8)。
葉緑体形質転換タバコにより生産されたAR19G-166-QV及びAR19G-166-RAのPSA加水分解活性の温度依存性を調べた。計測には、前記で得られた可溶性タンパク質抽出液を用いた。
各温度におけるPSA加水分解活性の計測は、前記で得られた可溶性タンパク質抽出液を用い、実施例1の<10>と同様に行い、酵素の加水分解によって生成した還元糖濃度を求めた。
糸状菌や植物など真核生物を宿主として任意の遺伝子を導入すると、発現したタンパク質は一般に至適温度が5~10℃程度上昇する。これは、グリコシル化(糖鎖修飾)と呼ばれる、タンパク質へ糖類が付加する翻訳後修飾反応によるものであり、グリコシル化されたタンパク質は熱に対し安定的になる。AR19G-166-RA及びAR19G-166-QV遺伝子のアミノ酸残基配列中に、N-結合型グリコシル化モチーフAsn-Xaa-Ser/Thrが4ヵ所、存在している。真核生物を宿主として遺伝子発現させると、これらモチーフおいて糖鎖修飾が起こる可能性があり、耐熱性の向上が期待される。アブラナ科の植物であるシロイヌナズナArabidopsis thalianaにAR19G-166-RA及びAR19G-166-QV遺伝子を導入し、コードする酵素タンパク質の耐熱性に対する糖鎖修飾の効果を検証した。
AR19G-166-RA及びAR19G-166-QV遺伝子をテンプレートにしてPCRを行い、アポプラスト蓄積型の植物発現ベクターpIG121Barに組み込んだ。前記発現ベクターを、凍結融解法を用いてアグロバクテリウム(Agrobacterium tumefaciens)に導入した。具体的には、氷中で融解したアグロバクテリウムEHA105株のコンピテントセルに、約1μgのプラスミド(発現ベクター)を加え、軽く混合した後、液体窒素を用いて瞬時に凍結させた。その後、37℃で4分間温めて融解し、0.5mLのSOC培地を加えて、28℃で1~3時間培養した。得られた培養液を、50mg/Lのカナマイシンと10mg/LのPPT(ホスフィノトリシン)を含有させたLB寒天培地に塗布し、28℃のインキュベーターで2日間静置培養することにより形質転換アグロバクテリウムを得た。形質転換アグロバクテリウムを液体培養後、プラスミドを抽出し3730 DNA Analyzerシーケンサ(ライフテクノロジーズ社製)を用いて配列確認を行った。
次に、22℃、24時間明期で約2ヶ月間生育させたシロイヌナズナ植物体と、50mg/Lのカナマイシンと10mg/LのPPTを含有させたLB培地を用いて培養した形質転換アグロバクテリウムを用いて、形質転換シロイヌナズナを作製した。
まず、OD600=1程度のアグロバクテリウム培養液を集菌後、5%シュークロース、0.05%シルウェット溶液に懸濁した。その後、シロイヌナズナ植物体をアグロバクテリウム懸濁液に数秒間浸け、種子への感染を行った。種子成熟後、回収し50mg/Lのカナマイシンと10mg/LのPPTを含有させた1/2MS培地を用いて形質転換体の選抜を行い、AR19G-166―RAについて6個体、AR19G-166―QVについて4個体、セロビオハイドロラーゼ形質転換シロイヌナズナを得た。このうちの2個体、Arabi_RA4、及び、Arabi_QV4について、セロビオハイドロラーゼ酵素活性を調査した。
前記タンパク質の抽出は、100mgの形質転換シロイヌナズナ個体の葉を液体窒素下で乳鉢及び乳棒を用いて粉砕した後、1mLの1容量%プロテアーゼインヒビターカクテル(シグマアルドリッチ社製)含有20mM 酢酸バッファー(pH5.5)を加え、よく混合した。得られた混合物を、2mLマイクロチューブに移して15,000rpm、4℃、10分間遠心分離を行って、上清を回収し、粗酵素抽出液とした。なお、野生型シロイヌナズナの葉を用いて、同様にして調製した粗酵素抽出液をコントロール(非形質転換区)とした。
AR19G-166-RAを導入したシロイヌナズナ形質転換体(Arabi_RA4)とAR19G-166-QVを導入したシロイヌナズナ形質転換体(Arabi_QV4)の粗酵素抽出液は、それぞれ、53.9kDaと52.1kDaに強いバンドが現れた。形質転換体Arabi_RA4の酵素タンパク質の分子量は形質転換体Arabi_QV4のそれより、やや大きい(図17のレーン2、3)。当該タンパク質を大腸菌で生産した場合のサイズは46.7kDaであり、シロイヌナズナを宿主として発現させたAR19G-166-RA遺伝子、及び、AR19G-166-QV遺伝子がコードするタンパク質は、見かけの分子量が、それぞれ、7.2kDaと5.4kDa増加した。この分子量増加は糖鎖付加によるものであり、形質転換体Arabi_RA4とArabi_QV4における発現酵素タンパク質の分子量の違いは、糖鎖付加の程度の違いによるものと考えられる。
当該遺伝子組換えシロイヌナズナ形質転換体により生産されたAR19G-166-RA酵素タンパク質、及びAR19G-166-QV酵素タンパク質のPSA加水分解活性の温度依存性を調べた。計測には、前記<2>で得られた粗酵素溶液を用い、実施例1の<10>と同様に行い、酵素の加水分解によって生成した還元糖量を求めた。
算出された各温度におけるPSA加水分解活性(還元糖量)を図18に示す。図18では、比較対照区として、野生型シロイヌナズナ植物体(WT)のセロビオハイドロラーゼ活性を計測し、プロットした。
シロイヌナズナをホストとして発現したAR19G-166-RA酵素タンパク質は、最も高い酵素活性を示した温度が計測上限の100℃であり、至適温度は100℃以上であると推定される。一方、AR19G-166-QV酵素タンパク質の至適温度は90℃であった。このように、AR19G-166遺伝子はシロイヌナズナ核ゲノム系において発現させると約10%分子量が増大し、至適温度が15~30℃上昇する。特に、シロイヌナズナ発現AR19G-166-RAは耐熱性に極めて優れており、好熱性糸状菌に由来する従来の耐熱性セロビオハイドロラーゼより至適温度が30℃以上も高い。
放線菌であるストレプトマイセス(Streptomyces)属細菌は、有用な抗生物質や生理活性物質を生産することで知られており、工業的に広く利用されている有用細菌である。その物質生産能を応用した外来遺伝子の大量発現系が開発され、いくつかの成功例が報告されている(特許文献3、4、5、非特許文献9、10、11)。特に放線菌は高GC含量のゲノムを持つため、大腸菌では発現が困難なGC含量の高い遺伝子の発現が良い傾向にあり(非特許文献11)、また異種タンパク質の発現が放線菌無細胞抽出液の40%にまで及ぶ極めて高いレベルの発現性も報告されている(非特許文献9)。本発明に係る耐熱性セロビオハイドロラーゼをより安価に大量生産するための手段としてAR19G-166-RA遺伝子を導入した放線菌における当該タンパク質の発現性を検証した。
pET101/D-TOPO ベクター(ライフテクノロジーズ社製)にクローニングされたAR19G-166-RA遺伝子をテンプレートにしてPCRにより放線菌発現ベクターpHSA81(特許文献4)に乗せ換え、ストレプトマイセス・リビダンスTK24株に形質転換した。前記TK24株はJohn Innes Centre (Norwich Research Park, Norwich, NR4 7UH, UK)等から入手可能である。
前記形質転換は、“Genetic manipulation of Streptomyces: a laboratory manual.”に記載の方法(プロトプラストポリエチレングリコール融合法)に準じて行なった。形質転換後、コロニーPCRによりポジティブクローンを選抜し、YEME培地(酵母エキス0.3%、バクトペプトン0.5%、麦芽エキス0.3%、グルコース1%、スクロース34%、MgCl2 5mM、グリシン0.5%)にて振とう培養後、組換えプラスミドを抽出し、3730 DNA Analyzerシーケンサ(ライフテクノロジーズ社製)を用いて配列確認を行った。
得られた形質転換体を5μg/mLのチオストレプトン含有YEME培地に植菌し28℃で5日間振とう培養し、遠心分離により集菌した。菌体を50mM Tris-HClバッファー(pH8.0)で洗浄後、培養液の1/10容量の同Bufferを加えて懸濁した。その後、超音波破砕装置BioRuptorUCD-200T(コスモバイオ社製)で30秒間破砕した後に30秒間休止する処理を10回行い、遠心後の上清(無細胞抽出液)を用いてSDS-PAGEを行なった結果を図19に示す。図19のレーン1はタンパク質分子量指標であり、レーン2は大腸菌発現AR19G-166-RA精製タンパク質(矢印)であり、レーン3はAR19G-166-RA遺伝子組換え放線菌Streptomces lividansの無細胞抽出液である。図19において、想定されるサイズ(46.7kDa)に目的タンパク質の強い発現を確認した(図19のレーン3)。
AR19G-166-RA遺伝子組換え放線菌の無細胞抽出液を用いてセロビオハイドロラーゼの活性測定を行なった。活性測定は50μLの無細胞抽出液試料、及び50μLの1質量%リン酸膨潤アビセル(PSA)含有200mM 酢酸バッファー(pH5.5)からなる混合液を、30~100℃で20分間反応させることにより行った。
基質溶液と酵素は、反応温度で5分間それぞれ別々に保温した後に混合し、反応開始とした。反応中、いずれの混合液も不溶性基質の沈殿を防ぐため、エッペンドルフ社のサーモミキサー(1400rpm)を用いて攪拌した。全ての計測において、50μLの1質量%リン酸膨潤アビセル(PSA)含有200mM 酢酸バッファー(pH5.5)のみを各温度で反応させ、反応停止の後に50μLの無細胞抽出液試料を加えた混合液をコントロール区とした。反応終了後は、等量の3,5-dinitrosalicylic acid reagent(DNS溶液)を加えて100℃で5分間加熱処理し、5分間の冷却後に遠心し、上清を得た。分光光度計を用いて前記上清の540nmの吸光度を計測し、グルコースで作成した検量線を用いて上清中の還元糖量を算出し、コントロール区との差分から酵素の加水分解によって生成した還元糖量を求めた。各計測は、3回の独立した試行により行い、平均値と標準誤差を求めた。その結果を図20に示す。図20では、各データポイントにおいて3回計測し、平均値と標準誤差を温度に対しプロットした。
1分間に1μmolの還元糖を生成する酵素活性を1Uとし、酵素タンパク質量で除した値を比活性(U/mg)とした場合、80℃における比活性は3.02であった。以上のように、AR19G-166-RAセロビオハイドロラーゼ酵素は放線菌においても良好な発現および活性を示したことから、本発明の遺伝子導入ホストとして利用できることが明らかになった。
セルラーゼの中には、セルロースを加水分解する触媒ドメインだけでなく、セルロース結合機能を持つモジュール(CBM、carbohydrate-binding module)を持つものがある。CBMそれ自身は分解活性を持たないが、単独でセルロースに結合する能力を有する。CBMの機能として、不溶性の基質に吸着することで、基質周辺におけるCBMに付随する触媒ドメインの濃度を上昇させてセルロースの分解速度を向上させたり、CBMの結合によってセルロース鎖間の水素結合を切り離して結晶構造を崩したりすることが知られている(非特許文献12、13)。また、結晶性セルロースを分解するCBHからCBMを除くと可溶性基質に対する反応性は変わらないにも係わらず、結晶性セルロースに対する分解活性や親和性が極端に低下することから、CBMは酵素が結晶性セルロースに作用するために必要なドメインであると考えられている(非特許文献14)。逆に、本来CBMを持たないエンドグルカナーゼの一種にCBMを付加することで結晶性セルロースへの親和性や分解能が上昇するという報告もある(非特許文献5)。
本発明に係る耐熱性セロビオハイドロラーゼのセルロース分解活性をより高めるための手段として、AR19G-166-RAにCBMを付加した遺伝子を作製し、そのコードする酵素タンパク質のセルロース分解活性に対するCBM付加の効果を検証した。
CBM配列およびリンカー配列は、実施例1<5>に示したオープンリーディングフレームOJ1-1の配列を用いた。AR19G-166-RA遺伝子のC末端側にオープンリーディングフレームOJ1-1のリンカー配列を付加し、そのC末端側にオープンリーディングフレームOJ1-1のCBM3配列を付加した。CBM付加AR19G-166-RA遺伝子全長の塩基配列を大腸菌のコドン使用頻度に最適化し、人工的に合成した。付加したリンカーおよびCBM3遺伝子のアミノ酸配列を配列番号17に、塩基配列を配列番号18に、大腸菌のコドン使用頻度に最適化したCBM付加AR19G-166-RA遺伝子全長のアミノ酸配列を配列番号19に、塩基配列を配列番号20に、それぞれ表す。配列番号18の808位から810位の3塩基TAA、及び配列番号20の2092位から2094位の3塩基TAAは何れもストップコドンである。
上述のように合成した遺伝子をExpression Vector pLEAD(NIPPON GENE社製)に組み込み、JM109株で形質転換を行い、ライフテクノロジーズ社の3730 DNA Analyzerシーケンサを用いて配列確認を行った。
配列確認後、目的遺伝子をもつプラスミドを保持していた大腸菌クローンを100mg/L アンピシリンを含むLB培地5mLに植菌し、37℃で20時間振とう培養した。培養後、遠心分離により大腸菌を回収し、培養液の1/10容量の50mM Tris-HClバッファー(pH8)を加えて懸濁した。その後、超音波破砕装置BioRuptorUCD-200T(コスモバイオ社製)で、30秒間破砕した後に30秒間休止する処理を10回行い、遠心後の上清(大腸菌粗抽出物)を得た。前記大腸菌粗抽出物の一部をSDS-PAGEにより泳動し、想定されるサイズに目的タンパク質の発現を確認した。タンパク質の発現確認後、37℃で一晩培養した大腸菌液を前培養液とし、その100倍量の100mg/L アンピシリンを含むLB培地で本培養を行った。
培養後、遠心分離を行って大腸菌を回収し、培養液の1/10容量の50mM Tris-HClバッファー(pH8)を加えて懸濁した。その後、超音波破砕装置astrason3000(MISONIX社製)を用いて、5分間破砕-5分間休止工程を7-8サイクル繰返し、目的タンパク質を含む遺伝子組換え大腸菌の粗抽出物を得た。当該遺伝子組換え大腸菌粗抽出物をフィルター(孔径φ=0.45μm、ミリポア社製)で濾過し、得られた濾液を遺伝子組換え大腸菌破砕上清とした。
図21A及び図21Bに、CBM付加AR19G-166-RAタンパク質を大腸菌に発現させて得られた酵素タンパク質のSDS-PAGE解析(図21A)とウェスタンブロット解析(図21B)の結果を示す。図21A及び図21Bのレーン1はタンパク質分子量指標であり、レーン2は遺伝子組換え大腸菌破砕上清であり、レーン3は精製したCBM付加AR19G-166-RAタンパク質であり、レーン4は実施例1の<9>で精製したセロビオハイドロラーゼ酵素タンパク質の電気泳動パターンである。
CBM付加AR19G-166-RAタンパク質よるPSAとAvicelの加水分解活性の温度依存性を調べた。計測には、前記で得られた精製酵素(終濃度約1mg/mL)を用いた。
精製酵素のPSAとAvicelに対する加水分解活性の測定は、100μLの1質量%基質水溶液と、50μLの200mM酢酸バッファー(pH5.5)と、40μLの精製水もしくは10mMのCaCl2水溶液と、10μLの精製酵素からなる混合液を、50、60、70、75、80、85、90、又は99℃で20分間反応させた以外は、実施例1の<10>と同様に行い、酵素の加水分解によって生成した還元糖量を求め、加水分解活性(U/mg)を算出した。
各温度における、CBM付加AR19G-166-RAタンパク質のPSA加水分解活性及びAvicel分解活性を図22A及び図22Bに示す。この結果、PSA分解活性においては、カルシウムイオンの存在の有無に関わらず、CBM付加の効果は認められず、AR19G-166-RAタンパク質単独による分解活性よりも、むしろ低下した(図22A)。ところが、Avicel分解活性においては、カルシウムイオン存在下において、50℃から85℃の広範な温度域で顕著な分解活性の上昇が見られた(図22B)。一方、カルシウムイオン非存在下では、70℃以上の温度域におけるAvicel分解活性の上昇は見られなかった。これは、CBMの熱安定性にカルシウムイオンが寄与していることを示している。
これらの結果から、本発明に係る耐熱性セロビオハイドロラーゼにCBMを付加させることにより、少なくともカルシウムイオンの存在下において、結晶性セルロースの加水分解活性を上昇させることができることは明らかである。
Claims (18)
- (A)配列番号1で表されるアミノ酸配列からなるポリペプチド、
(B)配列番号1で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(C)配列番号1で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(D)配列番号3で表されるアミノ酸配列からなるポリペプチド、
(E)配列番号3で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(F)配列番号3で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(G)配列番号5で表されるアミノ酸配列からなるポリペプチド、
(H)配列番号5で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(I)配列番号5で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
(J)配列番号7で表されるアミノ酸配列からなるポリペプチド、
(K)配列番号7で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、又は
(L)配列番号7で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチド、
からなるセロビオハイドロラーゼ触媒領域を有する、耐熱性セロビオハイドロラーゼ。 - さらに、セルロース結合モジュールを有する、請求項1に記載の耐熱性セロビオハイドロラーゼ。
- (a)配列番号1で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(b)配列番号1で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(c)配列番号1で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(d)配列番号3で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(e)配列番号3で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(f)配列番号3で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(g)配列番号5で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(h)配列番号5で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(i)配列番号5で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(j)配列番号7で表されるアミノ酸配列からなるポリペプチドをコードする塩基配列、
(k)配列番号7で表されるアミノ酸配列のうちの1若しくは複数個のアミノ酸が欠失、置換若しくは付加されたアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(l)配列番号7で表されるアミノ酸配列と80%以上100%未満の配列同一性を有するアミノ酸配列からなり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
(m)配列番号2、4、6、又は8で表される塩基配列と80%以上100%未満の配列同一性を有し、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、又は
(n)配列番号2、4、6、又は8で表される塩基配列からなるポリヌクレオチドとストリンジェントな条件でハイブリダイズするポリヌクレオチドの塩基配列であり、かつ少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドをコードする塩基配列、
からなるセロビオハイドロラーゼ触媒領域をコードする領域を有する、ポリヌクレオチド。 - さらに、セルロース結合モジュールをコードする領域を有する、請求項3に記載のポリヌクレオチド。
- 請求項3又は4に記載のポリヌクレオチドが組込まれており、
宿主細胞において、少なくとも75℃、pH5.5の条件下でセロビオハイドロラーゼ活性を有するポリペプチドを発現し得る、発現ベクター。 - 請求項5に記載の発現ベクターが導入されている、形質転換体。
- 原核生物である、請求項6に記載の形質転換体。
- 真核生物である、請求項6に記載の形質転換体。
- 植物である、請求項6に記載の形質転換体。
- 請求項6~9のいずれか一項に記載の形質転換体内で、耐熱性セロビオハイドロラーゼを生産する、耐熱性セロビオハイドロラーゼの製造方法。
- 請求項1に記載の耐熱性セロビオハイドロラーゼ、請求項2に記載の耐熱性セロビオハイドロラーゼ、又は請求項10に記載の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼと、少なくとも1種のその他のセルラーゼを含む、セルラーゼ混合物。
- 前記その他のセルラーゼが、ヘミセルラーゼ及びエンドグルカナーゼからなる群より選択される1種以上のセルラーゼである、請求項11に記載のセルラーゼ混合物。
- セルロースを含む材料を、請求項1に記載の耐熱性セロビオハイドロラーゼ、請求項2に記載の耐熱性セロビオハイドロラーゼ、請求項6~9のいずれか一項に記載の形質転換体、又は請求項10に記載の耐熱性セロビオハイドロラーゼの製造方法によって製造された耐熱性セロビオハイドロラーゼに接触させることにより、セルロース分解物を生産する、セルロース分解物の製造方法。
- 前記セルロースを含む材料に、さらに少なくとも1種のその他のセルラーゼを接触させる、請求項13に記載のセルロース分解物の製造方法。
- 前記その他のセルラーゼが、ヘミセルラーゼ及びエンドグルカナーゼからなる群より選択される1種以上のセルラーゼである、請求項14に記載のセルロース分解物の製造方法。
- 生物由来のDNA又は生物由来のRNAの逆転写産物を鋳型として、配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるフォワードプライマーと、配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるリバースプライマーと、を用いてPCRを行い、増幅産物として、耐熱性セロビオハイドロラーゼをコードする塩基配列を含むポリヌクレオチドを得る、耐熱性セロビオハイドロラーゼをコードするポリヌクレオチドの製造方法。
- 配列番号12で表される塩基配列、又は配列番号12で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるプライマー。
- 配列番号13で表される塩基配列、又は配列番号13で表される塩基配列の5’末端に1若しくは複数個の塩基が付加された塩基配列からなるプライマー。
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