JP6253465B2 - Mutant yeast belonging to the genus Kluyveromyces and method for producing ethanol using the same - Google Patents
Mutant yeast belonging to the genus Kluyveromyces and method for producing ethanol using the same Download PDFInfo
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E50/00—Technologies for the production of fuel of non-fossil origin
- Y02E50/10—Biofuels, e.g. bio-diesel
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- Preparation Of Compounds By Using Micro-Organisms (AREA)
- Micro-Organisms Or Cultivation Processes Thereof (AREA)
Description
本発明は、Kluyveromyces属酵母を利用した変異体酵母及びこれを用いたエタノールの製造方法に関する。 The present invention relates to a mutant yeast using Kluyveromyces genus yeast and a method for producing ethanol using the same.
リグノセルロースを含むバイオマスは、エタノール等の有用なアルコールや有機酸の原料として有効に利用されている。リグノセルロースを含むバイオマスには、木質系バイオマス及び草本系バイオマスが含まれる。木質系バイオマスなどのリグノセルロースを含むバイオマスは、主としてセルロース、ヘミセルロース及びリグニンから構成されている。リグノセルロースを含むバイオマスからエタノール等液体燃料を製造するためには、セルロースやヘミセルロースを構成単糖にまで加水分解(糖化)し、発酵によって単糖をエタノールに変換する。セルロースはグルコースから構成され、ヘミセルロースは主としてアラビノースとキシロースから構成されている。従って、リグノセルロースを含むバイオマスを利用してエタノールを製造する際には、グルコースのみではなくキシロースも発酵の基質として有効に利用されることが望ましい。 Biomass containing lignocellulose is effectively used as a raw material for useful alcohols such as ethanol and organic acids. The biomass containing lignocellulose includes woody biomass and herbaceous biomass. Biomass containing lignocellulose such as woody biomass is mainly composed of cellulose, hemicellulose and lignin. In order to produce a liquid fuel such as ethanol from biomass containing lignocellulose, cellulose or hemicellulose is hydrolyzed (saccharified) into constituent monosaccharides, and the monosaccharides are converted to ethanol by fermentation. Cellulose is composed of glucose, and hemicellulose is mainly composed of arabinose and xylose. Therefore, when ethanol is produced using biomass containing lignocellulose, it is desirable that not only glucose but also xylose is effectively used as a fermentation substrate.
また、リグノセルロースを含むバイオマスからエタノールを製造する場合、上述した糖化反応と発酵反応とを同時に(各反応工程を区別することなく)行うことができれば製造コストの低減に繋がる。これを同時糖化発酵方法と称する。同時糖化発酵には、糖化酵素の反応温度領域(約40℃以上)で発酵が可能な耐熱性を有し、基質としてグルコースのみでなく5炭糖のキシロースを利用できる微生物が必要となる。 Further, when ethanol is produced from biomass containing lignocellulose, production costs can be reduced if the saccharification reaction and the fermentation reaction described above can be performed simultaneously (without distinguishing each reaction step). This is called a simultaneous saccharification and fermentation method. Simultaneous saccharification and fermentation requires a microorganism that has heat resistance capable of fermentation in the saccharifying enzyme reaction temperature range (about 40 ° C. or higher) and can use not only glucose but also pentose xylose as a substrate.
耐熱性を有する酵母としては、Kluyveromyces marxianus等のKluyveromyces属酵母が知られている。このKluyveromyces属酵母は、キシロースを利用してエタノール発酵を行うことができるが、その収率は不十分であった。 As yeast having heat resistance, yeasts belonging to the genus Kluyveromyces such as Kluyveromyces marxianus are known. This Kluyveromyces genus yeast can perform ethanol fermentation using xylose, but its yield is insufficient.
一方、特許文献1は、Kluyveromyces属酵母におけるアルコールデヒドロゲナーゼ遺伝子(ADH1遺伝子又はADH4遺伝子)を減弱化することで当該酵母におけるキシロースからのエタノール収率が大幅に向上したことを開示する。また、特許文献2は、Kluyveromyces属酵母におけるトリオースホスフェートデヒドロゲナーゼ遺伝子(TDH1遺伝子又はTDH2遺伝子)を減弱化することで当該酵母におけるキシロースからのエタノール収率が大幅に向上したことを開示する。 On the other hand, Patent Document 1 discloses that by reducing the alcohol dehydrogenase gene (ADH1 gene or ADH4 gene) in Kluyveromyces genus yeast, the ethanol yield from xylose in the yeast is greatly improved. Patent Document 2 discloses that by reducing the triose phosphate dehydrogenase gene (TDH1 gene or TDH2 gene) in Kluyveromyces genus yeast, the ethanol yield from xylose in the yeast is greatly improved.
上述したように、Kluyveromyces属酵母は、キシロース資化性を有し、且つ耐熱性を有するため、上述した同時糖化発酵法等に有用な微生物として大きく期待されている。しかしながら、Kluyveromyces属酵母についてはキシロースからのエタノール収率が非常に悪い。そこで、本発明は、このような実情に鑑み、キシロースからのエタノール収率を向上するように改変されたKluyveromyces属に属する変異体酵母、及び当該変異体酵母を用いたエタノールの製造方法を提供することを目的とする。 As described above, Kluyveromyces yeasts are highly expected as microorganisms useful for the above-described simultaneous saccharification and fermentation methods and the like because they have xylose utilization and heat resistance. However, the yield of ethanol from xylose is very poor for Kluyveromyces genus yeast. Therefore, in view of such circumstances, the present invention provides a mutant yeast belonging to the genus Kluyveromyces modified so as to improve the ethanol yield from xylose, and a method for producing ethanol using the mutant yeast. For the purpose.
上述した目的を達成するため、本発明者らが鋭意検討した結果、Kluyveromyces属酵母において、基質としてキシロース利用時に、グルコース利用時と比較して高発現する特定の遺伝子を減弱化することで当該酵母におけるキシロースからのエタノール収率が大幅に向上することを見出し、本発明を完成するに至った。すなわち、本発明は以下を包含する。 As a result of intensive studies by the present inventors to achieve the above-mentioned object, in the yeast of the genus Kluyveromyces, when using xylose as a substrate, the specific gene that is highly expressed compared to when using glucose is attenuated. The present inventors have found that the ethanol yield from xylose is significantly improved in the present invention and completed the present invention. That is, the present invention includes the following.
(1)Kluyveromyces属に属する酵母における、基質としてキシロース利用時に、グルコース利用時と比較して高発現する遺伝子を減弱化した変異体酵母。
(2)上記Kluyveromyces属に属する酵母は、Kluyveromyces marxianusであることを特徴とする、(1)記載の変異体酵母。
(3)上記遺伝子が、Kluyveromyces marxianus由来ALD4遺伝子、MET8遺伝子、MTVK879遺伝子、MSSS1716遺伝子、YJR008W遺伝子、MSIN612遺伝子、MVNT843遺伝子、MSEI528遺伝子、MAMI1389遺伝子、YAL004W遺伝子、MLKP1164遺伝子、MTEG777遺伝子及びMQFK915遺伝子並びにこれらの遺伝子に機能的に等価な遺伝子から成る群から選ばれる少なくとも1つの遺伝子であることを特徴とする、(1)又は(2)記載の変異体酵母。
(4)上記ALD4遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号2のアミノ酸配列を含むタンパク質
(b) 配列番号2のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、アルデヒドデヒドロゲナーゼ活性を有するタンパク質
(c) 配列番号2のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含み、アルデヒドデヒドロゲナーゼ活性を有するタンパク質
(5)上記MET8遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号4のアミノ酸配列を含むタンパク質
(b) 配列番号4のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、二機能性デヒドロゲナーゼ及びフェロケラターゼ活性を有するタンパク質
(c) 配列番号4のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含み、二機能性デヒドロゲナーゼ及びフェロケラターゼ活性を有するタンパク質
(6)上記MTVK879遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号6のアミノ酸配列を含むタンパク質
(b) 配列番号6のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、L-キシルロースレダクターゼ活性を有するタンパク質
(c) 配列番号6のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含み、L-キシルロースレダクターゼ活性を有するタンパク質
(7)上記MSSS1716遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号8のアミノ酸配列を含むタンパク質
(b) 配列番号8のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、キシリトールトランスポーター活性を有するタンパク質
(c) 配列番号8のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含み、キシリトールトランスポーター活性を有するタンパク質
(8)上記YJR008W遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号10のアミノ酸配列を含むタンパク質
(b) 配列番号10のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号10のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(9)上記MSIN612遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号12のアミノ酸配列を含むタンパク質
(b) 配列番号12のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号12のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(10)上記MVNT843遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号14のアミノ酸配列を含むタンパク質
(b) 配列番号14のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、L-キシルロースレダクターゼ活性を有するタンパク質
(c) 配列番号14のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含み、L-キシルロースレダクターゼ活性を有するタンパク質
(11)上記MSEI528遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号16のアミノ酸配列を含むタンパク質
(b) 配列番号16のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号16のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(12)上記MAMI1389遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号18のアミノ酸配列を含むタンパク質
(b) 配列番号18のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号18のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(13)上記YAL004W遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号20のアミノ酸配列を含むタンパク質
(b) 配列番号20のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号20のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(14)上記MLKP1164遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号22のアミノ酸配列を含むタンパク質
(b) 配列番号22のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号22のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(15)上記MTEG777遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号24のアミノ酸配列を含むタンパク質
(b) 配列番号24のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号24のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(16)上記MQFK915遺伝子に機能的に等価な遺伝子は、Kluyveromyces marxianus以外のKluyveromyces属酵母に由来し、以下(a)〜(c)いずれかのタンパク質をコードすることを特徴とする、(3)記載の変異体酵母。
(a) 配列番号26のアミノ酸配列を含むタンパク質
(b) 配列番号26のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質
(c) 配列番号26のアミノ酸配列に対して1〜複数個のアミノ酸が欠失、置換、付加又は挿入したアミノ酸配列を含むタンパク質
(17)(1)〜(16)のいずれか1記載の変異体酵母をキシロース含有培地にて培養する工程と、その後、培地よりエタノールを回収する工程とを含む、エタノールの製造方法。
(18)上記培養する工程を、上記変異体酵母とリグノセルロースを含むバイオマスと糖化酵素とを含む反応系で実施することを特徴とする、(17)記載のエタノールの製造方法。
(1) A mutant yeast in which a gene that is highly expressed when using xylose as a substrate in yeast belonging to the genus Kluyveromyces is attenuated compared to when using glucose.
(2) The mutant yeast according to (1), wherein the yeast belonging to the genus Kluyveromyces is Kluyveromyces marxianus.
(3) The above genes are ALD4 gene derived from Kluyveromyces marxianus, MET8 gene, MTVK879 gene, MSSS1716 gene, YJR008W gene, MSIN612 gene, MVNT843 gene, MSEI528 gene, MAMI1389 gene, YAL004W gene, MLKP1164 gene, MTEG777 gene and MQFK915 gene The mutant yeast according to (1) or (2), wherein the mutant yeast is at least one gene selected from the group consisting of genes functionally equivalent to the gene.
(4) A gene functionally equivalent to the ALD4 gene is derived from a yeast of the genus Kluyveromyces other than Kluyveromyces marxianus, and encodes any one of the following proteins (a) to (c): (3) The mutant yeast described.
(a) a protein comprising the amino acid sequence of SEQ ID NO: 2
(b) a protein comprising an amino acid sequence having a sequence identity of 90% or more with respect to the amino acid sequence of SEQ ID NO: 2 and having an aldehyde dehydrogenase activity
(c) a protein having an aldehyde dehydrogenase activity comprising an amino acid sequence in which one or more amino acids have been deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 2 (5) functionally equivalent to the MET8 gene The mutant gene according to (3), wherein the gene is derived from a Kluyveromyces genus yeast other than Kluyveromyces marxianus, and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 4
(b) a protein comprising an amino acid sequence having a sequence identity of 90% or more with respect to the amino acid sequence of SEQ ID NO: 4 and having bifunctional dehydrogenase and ferrochelatase activities
(c) a protein having a bifunctional dehydrogenase and ferrochelatase activity, comprising an amino acid sequence in which one to a plurality of amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 4 (6) the MTVK879 gene The mutant yeast according to (3), wherein the functionally equivalent gene is derived from a Kluyveromyces genus yeast other than Kluyveromyces marxianus, and encodes any one of the following proteins (a) to (c).
(a) a protein comprising the amino acid sequence of SEQ ID NO: 6
(b) a protein having an amino acid sequence having a sequence identity of 90% or more with respect to the amino acid sequence of SEQ ID NO: 6 and having L-xylulose reductase activity
(c) a protein having an amino acid sequence in which one to a plurality of amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 6 and having L-xylulose reductase activity (7) functioning in the MSSS1716 gene The genetically equivalent gene is derived from Kluyveromyces genus yeast other than Kluyveromyces marxianus, and encodes any one of proteins (a) to (c) below, the mutant yeast according to (3).
(a) a protein comprising the amino acid sequence of SEQ ID NO: 8
(b) a protein having an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 8 and having xylitol transporter activity
(c) a protein having an amino acid sequence in which one or more amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 8 and having xylitol transporter activity (8) functionally related to the YJR008W gene The mutant yeast according to (3), wherein the equivalent gene is derived from a Kluyveromyces genus yeast other than Kluyveromyces marxianus and encodes any one of the following proteins (a) to (c).
(a) a protein comprising the amino acid sequence of SEQ ID NO: 10
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 10
(c) a protein comprising an amino acid sequence in which one to a plurality of amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 10 (9) A gene functionally equivalent to the MSIN612 gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 12
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 12
(c) a protein comprising an amino acid sequence in which one or more amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 12 (10) A gene functionally equivalent to the MVNT843 gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 14
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 14 and having L-xylulose reductase activity
(c) a protein having an amino acid sequence in which one to a plurality of amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 14 and having L-xylulose reductase activity (11) functions in the MSEI528 gene The genetically equivalent gene is derived from Kluyveromyces genus yeast other than Kluyveromyces marxianus, and encodes any one of proteins (a) to (c) below, the mutant yeast according to (3).
(a) a protein comprising the amino acid sequence of SEQ ID NO: 16
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 16
(c) a protein comprising an amino acid sequence in which one to a plurality of amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 16 (12) A gene functionally equivalent to the MAMI1389 gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 18
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 18
(c) a protein comprising an amino acid sequence in which one or more amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 18 (13) A gene functionally equivalent to the YAL004W gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 20
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 20
(c) a protein comprising an amino acid sequence in which one to a plurality of amino acids are deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 20 (14) A gene functionally equivalent to the above MLKP1164 gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 22
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 22
(c) a protein comprising an amino acid sequence in which one or more amino acids have been deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 22 (15) A gene functionally equivalent to the MTEG777 gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 24
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 24
(c) a protein comprising an amino acid sequence in which one or more amino acids have been deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 24 (16) A gene functionally equivalent to the MQFK915 gene is Kluyveromyces marxianus The mutant yeast according to (3), which is derived from a yeast other than Kluyveromyces and encodes any one of the following proteins (a) to (c):
(a) a protein comprising the amino acid sequence of SEQ ID NO: 26
(b) a protein comprising an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 26
(c) The mutation according to any one of (17) (1) to (16), which comprises an amino acid sequence in which one to a plurality of amino acids have been deleted, substituted, added or inserted into the amino acid sequence of SEQ ID NO: 26 A method for producing ethanol, comprising a step of culturing somatic yeast in a xylose-containing medium, and then a step of recovering ethanol from the medium.
(18) The method for producing ethanol according to (17), wherein the step of culturing is carried out in a reaction system comprising a biomass containing the mutant yeast, lignocellulose, and a saccharifying enzyme.
本発明に係る変異体酵母は、キシロースからのエタノール収率が大幅に向上している。従って、本発明に係る変異体酵母は、例えば、木質系バイオマス等のリグノセルロースを含むバイオマスに由来するキシロースを含む培地において、高収率にエタノールを製造することができる。 The mutant yeast according to the present invention has a significantly improved ethanol yield from xylose. Therefore, the mutant yeast according to the present invention can produce ethanol in a high yield in a medium containing xylose derived from biomass containing lignocellulose such as woody biomass.
本発明に係るエタノールの製造方法は、キシロースからのエタノール収率が大幅に向上した変異体酵母を利用することで、エタノール製造効率を大幅に向上させることができる。 The method for producing ethanol according to the present invention can greatly improve ethanol production efficiency by using a mutant yeast in which the ethanol yield from xylose is greatly improved.
本発明に係る変異体酵母は、Kluyveromyces属酵母における、基質としてキシロース利用時に、グルコース利用時と比較して高発現する(例えば、2倍以上発現する)特定の遺伝子を減弱化したものであり、キシロースからのエタノール収率が向上した特徴を有している。 The mutant yeast according to the present invention is a Kluyveromyces genus yeast, wherein xylose is used as a substrate, and a specific gene that is highly expressed (e.g., expressed twice or more) as compared with glucose is attenuated. The ethanol yield from xylose is improved.
ここで、Kluyveromyces属酵母とは、K. aestuarii、K. africanus、K. bacillisporus、K. blattae、K. dobzhanskii、K. hubeiensis、K. lactis、K. lodderae、K. marxianus、K. nonfermentans、K. piceae、K. sinensis、K. thermotolerans、K. waltii、K. wickerhamii及びK. yarrowii等の酵母を含む意味である。すなわち、本発明に係る変異体酵母は、これらの具体的なKluyveromyces属酵母及びその変異体に対して、キシロース利用時に高発現する特定の遺伝子を減弱化することで作製することができる。Kluyveromyces属酵母としては、特に、耐熱性酵母として知られているKluyveromyces marxianusを使用することが好ましい。Kluyveromyces marxianusとしては、特に限定されず、寄託機関に分譲可能に保存された公知の株を使用することができるし、また公知の株から派生した変異株を使用することもできる。Kluyveromyces marxianusの公知株としては、Kluyveromyces marxianus DMKU3-1042株を挙げることができる。公知の株から派生した変異株とは、例えば、Kluyveromyces marxianus DMKU3-1042株に対して栄養要求性を付与するためにura3遺伝子やleu2遺伝子を破壊した株を例示することができる。 Here, Kluyveromyces genus yeast is K. aestuarii, K. africanus, K. bacillisporus, K. blattae, K. dobzhanskii, K. hubeiensis, K. lactis, K. lodderae, K. marxianus, K. nonfermentans, K. It is meant to include yeasts such as piceae, K. sinensis, K. thermotolerans, K. waltii, K. wickerhamii and K. yarrowii. That is, the mutant yeast according to the present invention can be produced by attenuating a specific gene that is highly expressed when xylose is used relative to these specific Kluyveromyces yeasts and mutants thereof. As the Kluyveromyces genus yeast, it is particularly preferable to use Kluyveromyces marxianus known as a heat-resistant yeast. The Kluyveromyces marxianus is not particularly limited, and a known strain stored so as to be distributable at the depository can be used, and a mutant derived from the known strain can also be used. Examples of known strains of Kluyveromyces marxianus include Kluyveromyces marxianus DMKU3-1042 strain. Examples of mutant strains derived from known strains include strains in which the ura3 gene or leu2 gene is disrupted in order to impart auxotrophy to the Kluyveromyces marxianus DMKU3-1042 strain.
本発明に係る変異体酵母は、キシロース利用時に高発現する特定の遺伝子を減弱化したものである。ここで「遺伝子の減弱化」とは、当該遺伝子の発現量を低減すること、当該遺伝子がコードする酵素の活性を低減することの両者を含む意味である。例えば、キシロース利用時に高発現する特定の遺伝子を破壊又は欠失させる方法、当該遺伝子の発現制御領域(プロモーター等)を破壊又は欠失させる方法、当該遺伝子に対するアンチセンスRNAを発現する方法等により、当該遺伝子の発現量を低減することができる。また、所謂、トランスポゾン法、トランスジーン法、転写後遺伝子サイレンシング法、RNAi法、ナンセンス仲介減衰(Nonsense mediated decay, NMD)法、リボザイム法、アンチセンス法、miRNA(micro-RNA)法、siRNA(small interfering RNA)法等を適用し、当該遺伝子の発現量を低減することができる。さらに、キシロース利用時に高発現する特定の遺伝子によりコードされるタンパク質又は酵素の阻害剤を作用させる手法等により、当該遺伝子がコードするタンパク質又は酵素の活性を低減することができる。なお、これらの方法を組み合わせて、キシロース利用時に高発現する特定の遺伝子を減弱化しても良い。 The mutant yeast according to the present invention is an attenuated specific gene that is highly expressed when xylose is used. Here, “attenuation of the gene” means to reduce both the expression level of the gene and the activity of the enzyme encoded by the gene. For example, a method of destroying or deleting a specific gene that is highly expressed when using xylose, a method of destroying or deleting an expression control region of the gene (promoter, etc.), a method of expressing antisense RNA for the gene, etc. The expression level of the gene can be reduced. In addition, the so-called transposon method, transgene method, post-transcriptional gene silencing method, RNAi method, nonsense mediated decay (NMD) method, ribozyme method, antisense method, miRNA (micro-RNA) method, siRNA ( The expression level of the gene can be reduced by applying a small interfering RNA) method or the like. Furthermore, the activity of the protein or enzyme encoded by the gene can be reduced by a method of acting an inhibitor of the protein or enzyme encoded by a specific gene highly expressed when xylose is used. Note that these methods may be combined to attenuate specific genes that are highly expressed when xylose is used.
また、本発明に係る変異体酵母は、キシロースからのエタノール収率が向上した特徴を有している。言い換えると、本発明に係る変異体酵母は、キシロース代謝能が向上した特徴を有している。ここで、キシロース代謝能とは、培地に含まれるキシロースを代謝してアルコールとする発酵反応における効率を意味する。従って、キシロース代謝能の向上とは、当該発酵反応における反応効率を向上させることと同義となる。酵母におけるキシロース代謝能は、キシロース含有培地にて培養し、産生されたアルコールを定量することによって評価できる。また、酵母におけるキシロース代謝能は、例えば、培地に含まれるキシロースの取り込み速度(消費速度)を指標にして評価することもできる。キシロースの取り込み速度は、培養開始時における既知濃度のキシロースの減少量を経時的に測定することで算出することができる。 In addition, the mutant yeast according to the present invention has a feature that the ethanol yield from xylose is improved. In other words, the mutant yeast according to the present invention has a feature that the xylose metabolic ability is improved. Here, xylose metabolizing ability means the efficiency in the fermentation reaction that metabolizes xylose contained in the medium to produce alcohol. Therefore, the improvement of the xylose metabolic ability is synonymous with the improvement of the reaction efficiency in the fermentation reaction. The ability to metabolize xylose in yeast can be evaluated by culturing in a xylose-containing medium and quantifying the alcohol produced. The xylose metabolic capacity in yeast can also be evaluated using, for example, the uptake rate (consumption rate) of xylose contained in the medium as an index. The xylose uptake rate can be calculated by measuring the decrease in xylose at a known concentration at the start of culture over time.
本発明において、減弱化する遺伝子は、基質としてキシロース利用時に、グルコース利用時と比較して高発現する特定の遺伝子である。当該遺伝子としては、例えばKluyveromyces marxianusに存在するALD4遺伝子、MET8遺伝子、MTVK879遺伝子(LXR1遺伝子とも称する)、MSSS1716遺伝子(XST1遺伝子とも称する)、YJR008W遺伝子(MHO1遺伝子とも称する)、MSIN612遺伝子、MVNT843遺伝子(LXR2遺伝子とも称する)、MSEI528遺伝子、MAMI1389遺伝子、YAL004W遺伝子、MLKP1164遺伝子、MTEG777遺伝子及びMQFK915遺伝子が挙げられる。 In the present invention, the gene to be attenuated is a specific gene that is highly expressed when using xylose as a substrate compared to when using glucose. Examples of such genes include ALD4 gene, MET8 gene, MTVK879 gene (also referred to as LXR1 gene), MSSS1716 gene (also referred to as XST1 gene), YJR008W gene (also referred to as MHO1 gene), MSIN612 gene, MVNT843 gene (present in Kluyveromyces marxianus) LXIR2 gene), MSEI528 gene, MAMI1389 gene, YAL004W gene, MLKP1164 gene, MTEG777 gene and MQFK915 gene.
Kluyveromyces marxianus以外のKluyveromyces属酵母において減弱化する、キシロース利用時に高発現する特定の遺伝子は、上述のKluyveromyces marxianusに存在する遺伝子に機能的に等価な遺伝子である。 A specific gene that is attenuated in Kluyveromyces genus yeast other than Kluyveromyces marxianus and highly expressed when using xylose is a gene functionally equivalent to the gene present in Kluyveromyces marxianus described above.
Kluyveromyces marxianus以外のKluyveromyces属酵母において、Kluyveromyces marxianus由来の遺伝子に機能的に等価な遺伝子は、従来公知の方法により同定することができる。例えば、先ず、Kluyveromyces marxianus以外のKluyveromyces属酵母において各ホモログ遺伝子を特定する。そして、これら遺伝子がコードするタンパク質又は酵素のなかから、Kluyveromyces marxianus由来の遺伝子がコードするタンパク質又は酵素のアミノ酸配列に対して最も配列同一性が高いアミノ酸配列を有するものを特定する。このように特定したホモログ遺伝子は、Kluyveromyces marxianus由来の遺伝子と機能的に等価な遺伝子であると特定できる。ここで、配列同一性の値は、BLAST(Basic Local Alignment Search Tool)プログラムを実装したコンピュータを用いてデフォルトの設定で求められる値を意味する。 In yeasts of the genus Kluyveromyces other than Kluyveromyces marxianus, genes functionally equivalent to genes derived from Kluyveromyces marxianus can be identified by a conventionally known method. For example, first, each homologous gene is specified in Kluyveromyces genus yeast other than Kluyveromyces marxianus. Then, among the proteins or enzymes encoded by these genes, those having the amino acid sequence having the highest sequence identity to the amino acid sequence of the protein or enzyme encoded by the gene derived from Kluyveromyces marxianus are specified. The homologous gene thus identified can be identified as a gene that is functionally equivalent to a gene derived from Kluyveromyces marxianus. Here, the value of sequence identity means a value obtained by default setting using a computer equipped with a BLAST (Basic Local Alignment Search Tool) program.
ここで、Kluyveromyces marxianus由来の各遺伝子のコーディング領域の塩基配列及び当該遺伝子がコードするタンパク質のアミノ酸配列の配列番号並びに(機能不明ではない場合には)該タンパク質の活性又は機能は、以下の通りである:
ALD4遺伝子:配列番号1(塩基配列)、配列番号2(アミノ酸配列)、アルデヒドデヒドロゲナーゼ活性;
MET8遺伝子:配列番号3(塩基配列)、配列番号4(アミノ酸配列)、二機能性デヒドロゲナーゼ及びフェロケラターゼ活性;
MTVK879遺伝子:配列番号5(塩基配列)、配列番号6(アミノ酸配列)、L-キシルロースレダクターゼ活性;
MSSS1716遺伝子:配列番号7(塩基配列)、配列番号8(アミノ酸配列)、キシリトールトランスポーター活性;
YJR008W遺伝子:配列番号9(塩基配列)、配列番号10(アミノ酸配列);
MSIN612遺伝子:配列番号11(塩基配列)、配列番号12(アミノ酸配列);
MVNT843遺伝子:配列番号13(塩基配列)、配列番号14(アミノ酸配列)、L-キシルロースレダクターゼ活性;
MSEI528遺伝子:配列番号15(塩基配列)、配列番号16(アミノ酸配列);
MAMI1389遺伝子:配列番号17(塩基配列)、配列番号18(アミノ酸配列);
YAL004W遺伝子:配列番号19(塩基配列)、配列番号20(アミノ酸配列);
MLKP1164遺伝子:配列番号21(塩基配列)、配列番号22(アミノ酸配列);
MTEG777遺伝子:配列番号23(塩基配列)、配列番号24(アミノ酸配列);
MQFK915遺伝子:配列番号25(塩基配列)、配列番号26(アミノ酸配列)。
Here, the base sequence of the coding region of each gene derived from Kluyveromyces marxianus, the sequence number of the amino acid sequence of the protein encoded by the gene, and the activity or function of the protein (if the function is not unknown) are as follows: is there:
ALD4 gene: SEQ ID NO: 1 (base sequence), SEQ ID NO: 2 (amino acid sequence), aldehyde dehydrogenase activity;
MET8 gene: SEQ ID NO: 3 (base sequence), SEQ ID NO: 4 (amino acid sequence), bifunctional dehydrogenase and ferrochelatase activity;
MTVK879 gene: SEQ ID NO: 5 (base sequence), SEQ ID NO: 6 (amino acid sequence), L-xylulose reductase activity;
MSSS1716 gene: SEQ ID NO: 7 (base sequence), SEQ ID NO: 8 (amino acid sequence), xylitol transporter activity;
YJR008W gene: SEQ ID NO: 9 (base sequence), SEQ ID NO: 10 (amino acid sequence);
MSIN612 gene: SEQ ID NO: 11 (base sequence), SEQ ID NO: 12 (amino acid sequence);
MVNT843 gene: SEQ ID NO: 13 (base sequence), SEQ ID NO: 14 (amino acid sequence), L-xylulose reductase activity;
MSEI528 gene: SEQ ID NO: 15 (base sequence), SEQ ID NO: 16 (amino acid sequence);
MAMI1389 gene: SEQ ID NO: 17 (base sequence), SEQ ID NO: 18 (amino acid sequence);
YAL004W gene: SEQ ID NO: 19 (base sequence), SEQ ID NO: 20 (amino acid sequence);
MLKP1164 gene: SEQ ID NO: 21 (base sequence), SEQ ID NO: 22 (amino acid sequence);
MTEG777 gene: SEQ ID NO: 23 (base sequence), SEQ ID NO: 24 (amino acid sequence);
MQFK915 gene: SEQ ID NO: 25 (base sequence), SEQ ID NO: 26 (amino acid sequence).
なお、Kluyveromyces marxianusに存在する、これら遺伝子は、以上の具体的な塩基配列及びアミノ酸配列に限定されるものではない。すなわち、各遺伝子は、(機能不明ではない場合には)それぞれの酵素活性又は機能を有し、且つそれぞれの配列番号に示すアミノ酸配列に対して80%以上、好ましくは85%以上、より好ましくは90%以上、更に好ましくは95%以上、最も好ましくは98%以上の配列同一性を有するアミノ酸配列から成るタンパク質をコードするものも含まれる。ここで、配列同一性の値は、BLAST(Basic Local Alignment Search Tool)プログラムを実装したコンピュータを用いてデフォルトの設定で求められる値を意味する。 In addition, these genes existing in Kluyveromyces marxianus are not limited to the above specific base sequences and amino acid sequences. That is, each gene has a respective enzyme activity or function (when the function is not unknown) and is 80% or more, preferably 85% or more, more preferably relative to the amino acid sequence shown in each SEQ ID NO. Also included are those that encode proteins consisting of amino acid sequences having sequence identity of 90% or more, more preferably 95% or more, and most preferably 98% or more. Here, the value of sequence identity means a value obtained by default setting using a computer equipped with a BLAST (Basic Local Alignment Search Tool) program.
また、各遺伝子は、(機能不明ではない場合には)それぞれの酵素活性又は機能を有し、且つ、それぞれの配列番号に示すアミノ酸配列に対して1又は複数個(例えば2〜35個、好ましくは2〜30個、より好ましくは2〜20個、更に好ましくは2〜10個)のアミノ酸が欠失、置換、付加又は挿入されたアミノ酸配列から成るタンパク質をコードするものも含まれる。 Each gene has a respective enzyme activity or function (if the function is not unknown), and one or a plurality (for example, 2 to 35, preferably, for the amino acid sequence shown in each SEQ ID NO. 2-30, more preferably 2-20, and still more preferably 2-10) that encode a protein consisting of an amino acid sequence deleted, substituted, added or inserted.
さらに、各遺伝子は、(機能不明ではない場合には)それぞれの酵素活性又は機能を有するタンパク質をコードし、且つそれぞれの配列番号に示す塩基配列に相補的な塩基配列から成るポリヌクレオチドの一部又は全部に対して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も含まれる。ここで、ストリンジェントな条件とは、90%程度、好ましくは95%、更に好ましくは98%の同一性を有する一対のポリヌクレオチドが特異的なハイブリダイズを形成する条件(温度条件、塩濃度条件)を意味する。 Furthermore, each gene encodes a protein having the respective enzyme activity or function (if the function is not unknown), and a part of a polynucleotide comprising a base sequence complementary to the base sequence shown in each SEQ ID NO. Alternatively, a polynucleotide that hybridizes under stringent conditions with respect to the whole is also included. Here, stringent conditions are conditions under which a pair of polynucleotides having the identity of about 90%, preferably 95%, more preferably 98%, form a specific hybrid (temperature condition, salt concentration condition). ).
<エタノール製造>
以上で説明した変異体酵母を利用することで、キシロース等の糖を基質としたエタノール発酵を行うことができる。特に、上述した本発明に係る変異体酵母は、優れたキシロース代謝能、すなわちキシロースからのエタノール収率が優れているため、キシロース含有培地を利用したエタノール発酵に好適である。キシロース含有培地とは、Kluyveromyces属酵母が生育しうる培地であってエタノール合成の基質となる糖成分として少なくともキシロースを含有する培地を意味する。なお、キシロース含有培地は、キシロース以外の糖成分、例えばグルコースを含有していても良い。
<Ethanol production>
By using the mutant yeast described above, ethanol fermentation using a sugar such as xylose as a substrate can be performed. In particular, the mutant yeast according to the present invention described above is suitable for ethanol fermentation using a xylose-containing medium because it has an excellent ability to metabolize xylose, that is, an ethanol yield from xylose. The xylose-containing medium means a medium in which Kluyveromyces genus yeast can grow and contains at least xylose as a sugar component serving as a substrate for ethanol synthesis. The xylose-containing medium may contain a sugar component other than xylose, such as glucose.
キシロース含有培地は、特に限定されないが、SD培地、YPD培地、YPAD培地、YM培地及びYeast Nitrogen Baseを含む各種合成培地にキシロースを添加するか、これら公知の培地に含まれる糖成分をキシロースに代替することで調製することができる。 The xylose-containing medium is not particularly limited, but xylose is added to various synthetic media including SD medium, YPD medium, YPAD medium, YM medium and Yeast Nitrogen Base, or sugar components contained in these known mediums are replaced with xylose. Can be prepared.
また、木質系バイオマスや草本系バイオマスといったリグノセルロースを含むバイオマスからキシロース含有培地を調製しても良い。すなわち、リグノセルロースを含むバイオマスに含まれるセルロースやヘミセルロースを糖化処理し、得られた処理物をキシロース含有培地として使用することもできる。糖化処理としては、特に限定されず従来公知の手法をなんら限定されることなく利用することができる。糖化方法としては、例えば、希硫酸又は濃硫酸を利用する硫酸法、セルラーゼやヘミセルラーゼを利用する酵素法等を挙げることができる。また、糖化処理に先立って、木質系バイオマスや草本系バイオマスに対して従来公知の前処理を施しても良い。前処理としては、特に限定されないが、例えば、リグニンを微生物によって分解する処理や、木質系バイオマスや草本系バイオマスの粉砕処理、イオン液体やアルカリ溶液に浸漬して構造を緩和する処理、高温の水で蒸煮する水熱処理、アンモニアによる処理等を挙げることができる。 Moreover, you may prepare a xylose containing culture medium from biomass containing lignocellulose, such as woody biomass and herbaceous biomass. That is, cellulose or hemicellulose contained in biomass containing lignocellulose can be saccharified, and the resulting processed product can be used as a xylose-containing medium. The saccharification treatment is not particularly limited, and any conventionally known technique can be used without any limitation. Examples of the saccharification method include a sulfuric acid method using dilute sulfuric acid or concentrated sulfuric acid, and an enzymatic method using cellulase or hemicellulase. Prior to the saccharification treatment, woody biomass or herbaceous biomass may be subjected to conventionally known pretreatment. The pretreatment is not particularly limited. For example, a treatment for decomposing lignin by microorganisms, a pulverization treatment for woody biomass or herbaceous biomass, a treatment for relaxing the structure by immersion in an ionic liquid or an alkaline solution, high-temperature water Hydrothermal treatment of steaming, treatment with ammonia and the like.
特に、Kluyveromyces marxianusから作製した変異体酵母では、特に耐熱性に優れるため、例えば40℃以上、好ましくは35〜48℃、より好ましくは40〜42℃といった比較的に高温度でエタノール発酵を行うことができる。このような温度領域は、セルラーゼやヘミセルラーゼといった糖化酵素も活性を示す温度領域である。したがって、当該変異体酵母は、糖化酵素を利用した所謂、同時糖化発酵に好適である。ここで同時糖化発酵とは、糖化酵素による木質系バイオマスの糖化処理と、キシロースからのエタノール発酵処理とを同一反応系で実施する処理を意味する。より具体的には、木質系バイオマスと糖化酵素と変異体酵母とを含む溶液を例えば40℃といった温度条件にてインキュベートする。これにより、木質系バイオマスの糖化と、糖化によって得られたキシロースやグルコースからのエタノール発酵が進行し、エタノールを製造することができる。また、このとき溶液を攪拌しても良いし、振とうしてもよい。 In particular, mutant yeast prepared from Kluyveromyces marxianus is particularly excellent in heat resistance, so that ethanol fermentation is performed at a relatively high temperature, for example, 40 ° C or higher, preferably 35 to 48 ° C, more preferably 40 to 42 ° C. Can do. Such a temperature range is a temperature range in which saccharifying enzymes such as cellulase and hemicellulase are also active. Therefore, the mutant yeast is suitable for so-called simultaneous saccharification and fermentation using a saccharification enzyme. Here, the simultaneous saccharification and fermentation means a process in which saccharification treatment of woody biomass by saccharification enzyme and ethanol fermentation treatment from xylose are carried out in the same reaction system. More specifically, a solution containing woody biomass, saccharifying enzyme, and mutant yeast is incubated at a temperature condition of 40 ° C., for example. Thereby, saccharification of woody biomass and ethanol fermentation from xylose and glucose obtained by saccharification proceed to produce ethanol. At this time, the solution may be stirred or shaken.
また、培地に含まれるキシロース等の炭素源から発酵生産されたエタノールを回収する際には、特に限定されず、従来公知のいかなる方法も適用することができる。例えば、上述したエタノール発酵が終了した後、固液分離操作によってエタノールを含む液層と、変異体酵母や固形成分を含有する固層とを分離する。その後、液層に含まれるエタノールを蒸留法によって分離・精製することで、純度の高いエタノールを回収することができる。なお、エタノールの精製度は、エタノールの使用目的にあわせて適宜調整することができる。 In addition, when recovering ethanol produced by fermentation from a carbon source such as xylose contained in the medium, any conventionally known method can be applied without particular limitation. For example, after the above-described ethanol fermentation is completed, a liquid layer containing ethanol and a solid layer containing mutant yeast and solid components are separated by a solid-liquid separation operation. Thereafter, ethanol contained in the liquid layer is separated and purified by a distillation method, whereby high purity ethanol can be recovered. The purity of ethanol can be adjusted as appropriate according to the intended use of ethanol.
以下、実施例により本発明をより詳細に説明するが、本発明の技術的範囲は以下の実施例に限定されるものではない。 EXAMPLES Hereinafter, although an Example demonstrates this invention in detail, the technical scope of this invention is not limited to a following example.
〔実施例1〕
キシロース資化時の次世代シークエンス転写解析
<方法>
次世代シークエンス解析用の酵母培養は、Kluyveromyces marxianus DMKU3-1042株をYPD(2% glucose)培地とYPX(2% xylose)培地で18時間培養を行い、RNAを抽出し、北海道システム・サイエンス社に送付した。
[Example 1]
Next-generation sequence transcription analysis during xylose utilization <Method>
For yeast culture for next-generation sequencing analysis, Kluyveromyces marxianus DMKU3-1042 strain was cultured in YPD (2% glucose) medium and YPX (2% xylose) medium for 18 hours, RNA was extracted, and Hokkaido System Science Co., Ltd. delivered.
また、次世代シークエンス解析は、Illumina GAIIによるSingle-End法を用いたmRNAシークエンスを行った。 In the next-generation sequence analysis, mRNA sequence using the Illumina GAII single-end method was performed.
得られたデータは、用意したドラフトゲノムにアセンブルし、マッピングされた領域を抽出し、その領域100 bpあたりのリード数を計算することでその領域の転写量を示した。 The obtained data was assembled into a prepared draft genome, the mapped region was extracted, and the number of reads per 100 bp of the region was calculated to show the transcription amount of that region.
データ解析は、ORF領域を完全に含むリード領域をまず洗い出し、その中からYPDとYPXとを比較した。YPDとYPXとの比較では、各培地における遺伝子発現量の比を調べ、高発現ではなくてもYPXで発現が増加した遺伝子をリストアップした。 In the data analysis, first, a lead region completely including the ORF region was identified, and YPD and YPX were compared with each other. In comparison between YPD and YPX, the ratio of gene expression in each medium was examined, and genes whose expression was increased by YPX were listed even if not high expression.
YPDでは2202のORFがマップされ、一方、YPXでは1992のORFがマップされた。YPXでYPDの2倍以上の発現量を示したものをリストアップし、それらの遺伝子の特徴で分類した。分類後、細胞壁合成、タンパク質合成等に関連する遺伝子を除き、代謝関連遺伝子と機能未知遺伝子を抽出した。 YPD mapped 2202 ORFs, while YPX mapped 1992 ORFs. Those that expressed more than twice the amount of YPD in YPX were listed and classified according to their gene characteristics. After classification, genes related to metabolism and unknown function were extracted except genes related to cell wall synthesis and protein synthesis.
<結果>
結果を表1に示す。
<Result>
The results are shown in Table 1.
ALD4はYPDでは発現が観察されていない。便宜的に発現倍率(YPX/YPD)を208倍とした。
表1に示すように、基質としてキシロース利用時にグルコース利用時と比較して高発現する遺伝子の中で、ALD4遺伝子は、アルデヒドデヒドロゲナーゼ遺伝子である。MET8遺伝子も、またデヒドロゲナーゼ遺伝子である。
ALD4 is not observed in YPD. For convenience, the expression magnification (YPX / YPD) was set to 208 times.
As shown in Table 1, the ALD4 gene is an aldehyde dehydrogenase gene among genes that are highly expressed when using xylose as a substrate compared to when using glucose. The MET8 gene is also a dehydrogenase gene.
MTVK879遺伝子とMVNT843遺伝子は、相同性検索からL-xylulose reductaseとの相同性がみられた。L-xylulose reductaseはD-xylulose reductaseと似たxylitol dehydrogenaseであり、xylitolをD-xyluloseに変換するか、L-xyluloseに変換するかの違いがある。 MTVK879 gene and MVNT843 gene showed homology with L-xylulose reductase by homology search. L-xylulose reductase is an xylitol dehydrogenase similar to D-xylulose reductase, and there is a difference between converting xylitol to D-xylulose or converting to L-xylulose.
また、MTVK879遺伝子は、Candida dubliniensis CD36におけるL-xylulose reductaseと68%の相同性をもつ。この遺伝子をLXR1と命名した。 The MTVK879 gene has 68% homology with L-xylulose reductase in Candida dubliniensis CD36. This gene was named LXR1.
さらに、MVNT843遺伝子は、Aspergillus oryzae RIB40のL-xylulose reductaseの配列と95%の相同性をもっている。MVNT843破壊株はキシロースやキシリトールを資化できるが、アラビノースを資化できないという結果となったため、MVNT843遺伝子はL-xylulose reductaseをコードする遺伝子であると考えられる。この遺伝子をLXR2と命名した。 Furthermore, the MVNT843 gene has 95% homology with the L-xylulose reductase sequence of Aspergillus oryzae RIB40. The MVNT843 disruption strain was able to assimilate xylose and xylitol, but could not assimilate arabinose. Therefore, the MVNT843 gene is considered to be a gene encoding L-xylulose reductase. This gene was named LXR2.
MSSS1716遺伝子は、糖のトランスポーターとの相同性を持つ。キシリトールの資化性に影響が出たので、キシリトールトランスポーター遺伝子であると予想した。この遺伝子をXST1と命名した。 The MSSS1716 gene has homology to sugar transporters. Since the utilization of xylitol was affected, it was expected to be a xylitol transporter gene. This gene was named XST1.
YJR008W遺伝子は、S. cerevisiaeのYJR008W遺伝子と相同性があり、YJR008W遺伝子はMHO1と命名されている。 The YJR008W gene is homologous to the S. cerevisiae YJR008W gene, and the YJR008W gene is designated MHO1.
YAL004W遺伝子は、S. cerevisiaeのYAL004W遺伝子と相同性があり、この遺伝子はSSA1とオーバーラップしている。 The YAL004W gene is homologous to the S. cerevisiae YAL004W gene and this gene overlaps with SSA1.
その他の遺伝子は、S. cerevisiaeとは相同性がないので、ORF名としてそれぞれの名前を便宜的に与えた。 Since other genes have no homology with S. cerevisiae, each name was given as an ORF name for convenience.
〔実施例2〕
本実施例では、Kluyveromyces属酵母としてKluyveromyces marxianusを使用し、実施例1においてキシロース利用時に高発現するものとして見出された各遺伝子(ALD4遺伝子、MET8遺伝子、MTVK879(LXR1)遺伝子、MSSS1716(XST1)遺伝子、YJR008W(MHO1)遺伝子、MSIN612遺伝子、MVNT843(LXR2)遺伝子、MSEI528遺伝子、MAMI1389遺伝子、YAL004W遺伝子、MLKP1164遺伝子、MTEG777遺伝子及びMQFK915遺伝子)の破壊株を作製し、キシロースからのエタノール収率を比較検討した。
[Example 2]
In this example, Kluyveromyces marxianus was used as a yeast belonging to the genus Kluyveromyces, and each gene (ALD4 gene, MET8 gene, MTVK879 (LXR1) gene, MSSS1716 (XST1), which was found to be highly expressed when using xylose in Example 1) Gene, YJR008W (MHO1) gene, MSIN612 gene, MVNT843 (LXR2) gene, MSEI528 gene, MAMI1389 gene, YAL004W gene, MLKP1164 gene, MTEG777 gene and MQFK915 gene), and compare ethanol yield from xylose investigated.
<株の作製>
接合、胞子形成によるura3- leu2-変異株の作製
Kluyveromyces marxianus DMKU3-1042株のura3-株であるRAK3605株(Nonklang, S. et al., Appl. Environ. Microbiol. 74: 7514-7521, 2008)を基準株として使用した。K. marxianus DMKU3-1042株由来の栄養要求性変異株は、低頻度で2倍体になることを明らかにしている。紫外線変異により、多重栄養要求性変異株を取得することは可能であるが、その結果、染色体DNAに変異が入る確率が上昇する。より安定な株を作製するために、接合と胞子形成により、2倍体から簡単に多重栄養要求性株を作製する(Yarimizu, T. et al., Yeast 30: 485-500, 2013)ために以下の株を作製した。
<Production of strain>
Production of ura3-leu2-mutant strain by conjugation and sporulation
RAK3605 strain (Nonklang, S. et al., Appl. Environ. Microbiol. 74: 7514-7521, 2008), which is a ura3- strain of Kluyveromyces marxianus DMKU3-1042, was used as a reference strain. An auxotrophic mutant derived from K. marxianus DMKU3-1042 has been shown to be diploid at a low frequency. Although it is possible to obtain multiple auxotrophic mutants by ultraviolet mutation, the probability of mutations in chromosomal DNA increases as a result. To create a more auxotrophic strain from diploids by conjugation and sporulation to create a more stable strain (Yarimizu, T. et al., Yeast 30: 485-500, 2013) The following strains were produced:
先ず、RAK3605株に紫外線照射し、lys-株(RAK3896株:ura3- lys2-)、ade-株(RAK3919株:ura3- ade2-)及びleu-株(RAK3966株:ura3- leu2-)を取得した。これらの株にSaccharomyces cerevisiaeのURA3をランダムに染色体へ形質転換した株、RAK4088株(ura3- leu2- ScURA3)、RAK4152株(ura3- ade2- ScURA3)、RAK4153株(ura3- lys2- ScURA3)を作製した。RAK4152とRAK4153株をYPD培地(1% w/v Yeast extract, 2% w/v peptone, 2% glucose, 2% w/v agar)上で混ざるようにストリークし、MM培地(0.17% w/v yeast nitrogen base w/o amino acids and ammonium sulfate, 0.5% w/v ammonium sulfate, 2% w/v glucose, 2% w/v agar)へレプリカした。MM培地で生えた株、RAK4154株(ura3-/ura3- ade2-/ADE2, lys2-/LYS2 ScURA3/ScURA3)をS. cerevisiaeで使用されるSPO培地(1% w/v potassium acetate, 0.1% w/v yeast extract, 0.05% w/v glucose)に植菌し、胞子形成させた。 First, RAK3605 strain was irradiated with ultraviolet rays to obtain lys- strain (RAK3896 strain: ura3-lys2-), ade- strain (RAK3919 strain: ura3-ade2-) and leu- strain (RAK3966 strain: ura3-leu2-) . Saccharomyces cerevisiae URA3 strains were randomly transformed into chromosomes, RAK4088 strain (ura3-leu2- ScURA3), RAK4152 strain (ura3-ade2- ScURA3), and RAK4153 strain (ura3-lys2- ScURA3). . Streak the RAK4152 and RAK4153 strains on YPD medium (1% w / v Yeast extract, 2% w / v peptone, 2% glucose, 2% w / v agar), and add MM medium (0.17% w / v yeast nitrogen base w / o amino acids and ammonium sulfate, 0.5% w / v ammonium sulfate, 2% w / v glucose, 2% w / v agar). Strains grown in MM medium, RAK4154 strain (ura3- / ura3-ade2- / ADE2, lys2- / LYS2 ScURA3 / ScURA3) were used in S. cerevisiae SPO medium (1% w / v potassium acetate, 0.1% w / v yeast extract, 0.05% w / v glucose) to form spores.
作製した胞子を分離し、ura- lys- ade-の3重栄養要求性株を取得するために、-A培地(MM+uracil, tryptophan, histidine HCl, methionine, leucine, lysine HCl), -K培地(MM+ uracil, tryptophan, histidine HCl, methionine, leucine, adenine hemisulfate), -U培地(MM+ tryptophan, histidine HCl, methionine, leucine, lysine HCl, adenine hemisulfate)へレプリカし、3つの培地で増殖できない株をRAK4154株の胞子から3株取得することに成功した。その株をRAK4155株(ura3- lys2- ade2-)と命名した。同様の方法でRAK4088株とRAK4155株を接合させ、RAK4156株(ura3-/ura3- lys2-/LYS2 ade2-/ADE2 leu2-/LEU2 ScURA3/ScURA3)を作製した。この株を胞子形成させ、RAK4174株(leu2- ura3-)株を作製した。 -A medium (MM + uracil, tryptophan, histidine HCl, methionine, leucine, lysine HCl), -K medium to isolate the prepared spores and obtain triple auxotrophic strains of ura-lys-ade- (MM + uracil, tryptophan, histidine HCl, methionine, leucine, adenine hemisulfate), -U medium (MM + tryptophan, histidine HCl, methionine, leucine, lysine HCl, adenine hemisulfate) Succeeded in acquiring 3 strains from the spores of the strain. This strain was named RAK4155 strain (ura3-lys2-ade2-). In the same manner, the RAK4088 strain and the RAK4155 strain were joined to produce the RAK4156 strain (ura3- / ura3-lys2- / LYS2 ade2- / ADE2 leu2- / LEU2 ScURA3 / ScURA3). This strain was sporulated to produce the strain RAK4174 (leu2-ura3-).
Ku70破壊株の作製
K. marxianusは非相同末端結合修復が高頻度で起こることから、S. cerevisiaeのように相同組換え修復を利用して遺伝子破壊を容易に行うことができない(Nonklang, S. et al., Appl. Environ. Microbiol. 74: 7514-7521, 2008)。そこで、非相同末端結合修復に必須のKU70遺伝子を破壊することで相同組換えを高頻度に起こさせる株の作製を行った。RAK4174株からKU70を破壊したRAK4736株(ura3-1 leu2-2 ku70Δ::ScLEU2)を作製した(Abdel-Banat, B. M. et al., Yeast 27: 29-39, 2010)。
Production of Ku70 disruption strain
Since K. marxianus has high frequency of non-homologous end-joining repair, it cannot be easily disrupted using homologous recombination repair like S. cerevisiae (Nonklang, S. et al., Appl. Environ. Microbiol. 74: 7514-7521, 2008). Therefore, a strain that causes homologous recombination at a high frequency by disrupting the KU70 gene essential for non-homologous end-joining repair was prepared. The RAK4736 strain (ura3-1 leu2-2 ku70Δ :: ScLEU2) in which KU70 was disrupted from the RAK4174 strain was prepared (Abdel-Banat, BM et al., Yeast 27: 29-39, 2010).
Ku70破壊株をホスト株とした遺伝子破壊株の取得
使用したプライマーを以下の表2に示す。
Table 2 below shows primers used for obtaining and destroying gene-disrupted strains using Ku70-disrupted strains as host strains .
Ku70破壊株をホスト株として形質転換を行う方法で遺伝子を破壊した。fragmentとして、URA3マーカーの両端に目的遺伝子(破壊遺伝子)のORF内の相同配列を持たせたDNA断片を作製し、形質転換に用いた。 The gene was disrupted by the transformation method using Ku70 disrupted strain as the host strain. As a fragment, a DNA fragment having a homologous sequence in the ORF of the target gene (disruption gene) at both ends of the URA3 marker was prepared and used for transformation.
具体的には、S. cerevisiaeのBY4702株(MATa ade2Δ::hisG his3Δ200 leu2Δ0 lys2Δ0 met15Δ0 trp1Δ63, Brachmann, C. B. et al., Yeast 14: 115-132, 1998)の染色体DNAをテンプレートとして、9C-URA3-223及び3CG9-URA3+880cの2つのプライマーでKOD Plusを用いてPCRを行い、次いで、その産物をURA3テンプレート(50 ng/μl)とし、以下の表3のプライマーセットでURA3マーカーの両端に破壊遺伝子のORF内の相同配列を付けたDNA断片をPCRにより作製した。次いで、得られた各DNA断片を、RAK4736株へ形質転換し、相同組換えにより各破壊遺伝子を破壊した。 Specifically, by using the chromosomal DNA of BY4702 strain of S. cerevisiae (MATa ade2Δ :: hisG his3Δ200 leu2Δ0 lys2Δ0 met15Δ0 trp1Δ63, Brachmann, CB et al., Yeast 14: 115-132, 1998) as a template, 9C-URA3- Perform PCR using KOD Plus with two primers 223 and 3CG9-URA3 + 880c, then use the product as a URA3 template (50 ng / μl) and destroy at both ends of the URA3 marker with the primer set in Table 3 below. A DNA fragment with a homologous sequence in the ORF of the gene was prepared by PCR. Subsequently, each obtained DNA fragment was transformed into RAK4736 strain, and each disrupted gene was disrupted by homologous recombination.
当該形質転換に使用した培地は、YPD(1% yeast extract, 2% polypepton, 2% glucose)とウラシル欠損培地(0.17% yeast nitrogen base without amino acids and without ammonium sulfate, 0.5% ammonium sulfate, 2% glucose,及び必要なアミノ酸類)である。 The medium used for the transformation was YPD (1% yeast extract, 2% polypepton, 2% glucose) and uracil deficient medium (0.17% yeast nitrogen base without amino acids and without ammonium sulfate, 0.5% ammonium sulfate, 2% glucose. , And necessary amino acids).
DNAの抽出は、細胞壁溶解酵素を用いた方法とコロニーPCRを行った。コロニーPCR法は、20 mM NaOHをPCRチューブに5μlいれ、そこに酵母コロニーの一部を混ぜ、100℃に10分間置いたのち15℃で冷却した。冷却後、水を15μl入れて調整した。 Extraction of DNA was performed by a method using cell wall lytic enzyme and colony PCR. In the colony PCR method, 5 μl of 20 mM NaOH was added to a PCR tube, a portion of the yeast colony was mixed there, placed at 100 ° C. for 10 minutes, and then cooled at 15 ° C. After cooling, 15 μl of water was added for adjustment.
PCRにはKOD Plus (TOYOBO)及びKOD FX Neo (TOYOBO)を使用した。KOD Plusは形質転換用のDNA Fragmentを作製するために、KOD FX NeoはコロニーPCRに利用した。PCR産物の濃度測定はInvitrogen Quant iTTMdsDNA BRキットを用い,蛍光光度計(Invitrogen Quant iTTM fluorometer)で測定した。 For PCR, KOD Plus (TOYOBO) and KOD FX Neo (TOYOBO) were used. KOD Plus was used for colony PCR in order to prepare DNA Fragment for transformation. The concentration of the PCR product was measured with a fluorimeter (Invitrogen Quant iT ™ fluorometer) using the Invitrogen Quant iT ™ dsDNA BR kit.
酵母の形質転換は、以下のように行った。YPD液体培地3 mlに酵母を植えて28℃、150 rpmで18〜24時間振とう培養した。その酵母培養液1 mlとYPD液体培地9 mlを混合し、28℃、150 rpmで5時間振とう培養した。全量を15 mlチューブに移して8000 rpmで3分間遠心して上清を捨てた。その後、60 % ポリエチレングリコール3350 784μl、4 M 酢酸リチウム59μl、滅菌した脱イオン水157μlを混ぜた形質転換液200μlを、さきほど上清を捨てた15 mlチューブにいれてよく撹拌し、8000 rpmで3分間遠心して上清を捨てた。そして、形質転換液180μlを加えてよく撹拌した。この状態の細胞を81μl、キャリアDNA(salmon testes DNA, Sigma D-1626, 10 mg/ml) 10μl、PCRしたDNA断片3〜5μlを混ぜて42℃、30分間インキュベートした。その後、液体の選択培地を100μl加えて、選択培地プレート上にまいた。28℃のインキュベータで4〜5日培養した。 Transformation of yeast was performed as follows. Yeast was planted in 3 ml of YPD liquid medium and cultured with shaking at 28 ° C. and 150 rpm for 18 to 24 hours. 1 ml of the yeast culture and 9 ml of YPD liquid medium were mixed and cultured with shaking at 28 ° C. and 150 rpm for 5 hours. The whole amount was transferred to a 15 ml tube, centrifuged at 8000 rpm for 3 minutes, and the supernatant was discarded. Then, add 200 μl of the transformation solution containing 3% 784 μl of 60% polyethylene glycol, 59 μl of 4 M lithium acetate, and 157 μl of sterilized deionized water in a 15 ml tube from which the supernatant was discarded, and mix well at 8000 rpm. The supernatant was discarded after centrifugation for min. Then, 180 μl of the transformation solution was added and stirred well. 81 μl of cells in this state, 10 μl of carrier DNA (salmon testes DNA, Sigma D-1626, 10 mg / ml), and 3 to 5 μl of the PCR DNA fragment were mixed and incubated at 42 ° C. for 30 minutes. Thereafter, 100 μl of liquid selective medium was added and spread on the selective medium plate. The cells were cultured for 4 to 5 days in an incubator at 28 ° C.
このようにして、ALD4破壊株(RAK8673株:ura3-1 leu2-2 ku70Δ::ScLEU2 ald4Δ::ScURA3)、MET8破壊株(RAK8671株:ura3-1 leu2-2 ku70Δ::ScLEU2 met8Δ::ScURA3)、MTVK879破壊株(RAK9797株:ura3-1 leu2-2 ku70Δ::ScLEU2 lxr1Δ::ScURA3)、MSSS1716破壊株(RAK8848株:ura3-1 leu2-2 ku70Δ::ScLEU2 xst1Δ::ScURA3)、YJR008W破壊株(RAK8846株:ura3-1 leu2-2 ku70Δ::ScLEU2 mho1Δ::ScURA3)、MSIN612破壊株(RAK9914株:ura3-1 leu2-2 ku70Δ::ScLEU2 msin612Δ::ScURA3)、MVNT843破壊株(RAK8777株:ura3-1 leu2-2 ku70Δ::ScLEU2 lxr2Δ::ScURA3)、MSEI528破壊株(RAK8803株:ura3-1 leu2-2 ku70Δ::ScLEU2 msei528Δ::ScURA3)、MAMI1389破壊株(RAK9799株:ura3-1 leu2-2 ku70Δ::ScLEU2 mami1389Δ::ScURA3)、YAL004W破壊株(RAK8799株:ura3-1 leu2-2 ku70Δ::ScLEU2 yal004wΔ::ScURA3)、MLKP1164破壊株(RAK9801株:ura3-1 leu2-2 ku70Δ::ScLEU2 mlkp1164Δ::ScURA3)、MTEG777破壊株(RAK8801株:ura3-1 leu2-2 ku70Δ::ScLEU2 mteg777Δ::ScURA3)及びMQFK915破壊株(RAK8805株:ura3-1 leu2-2 ku70Δ::ScLEU2 mqfk915Δ::ScURA3)を作製した。 Thus, ALD4 disruption strain (RAK8673 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 ald4Δ :: ScURA3), MET8 disruption strain (RAK8671 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 met8Δ :: ScURA3) , MTVK879 disruption strain (RAK9797 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 lxr1Δ :: ScURA3), MSSS1716 disruption strain (RAK8848 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 xst1Δ :: ScURA3), YJR008W disruption strain (RAK8846 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 mho1Δ :: ScURA3), MSIN612 disruption strain (RAK9914 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 msin612Δ :: ScURA3), MVNT843 disruption strain (RAK8777 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 lxr2Δ :: ScURA3), MSEI528 disrupted strain (RAK8803 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 msei528Δ :: ScURA3), MAMI1389 disrupted strain (RAK9799 strain: ura3-1 leu2 -2 ku70Δ :: ScLEU2 mami1389Δ :: ScURA3), YAL004W disruption strain (RAK8799 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 yal004wΔ :: ScURA3), MLKP1164 disruption strain (RAK9801 strain: ura3-1 leu2-2 ku70Δ: : ScLEU2 mlkp1164Δ :: ScURA3), MTEG777 disruption strain (RAK8801 strain: ura3-1 leu2-2 ku70Δ :: ScLEU2 mteg777Δ :: ScURA3) and MQFK915 disruption strain (RAK8805 strain: ur a3-1 leu2-2 ku70Δ :: ScLEU2 mqfk915Δ :: ScURA3).
なお、各遺伝子破壊株における遺伝子破壊は、以下の表4に示すプライマーセットを使用して確認した。 In addition, gene disruption in each gene disruption strain was confirmed using a primer set shown in Table 4 below.
<エタノール発酵試験>
以上のように作製された各破壊株についてキシロースを利用したエタノール発酵試験を行った。
<Ethanol fermentation test>
An ethanol fermentation test using xylose was performed on each disrupted strain prepared as described above.
前培養
YPX(キシロース20g/L)培地20mlを加えた50mlアシストチューブに上記破壊株を一白金耳植菌し、30℃、140rpmで6〜8時間振とう培養した。次に、その菌液2.5%を、YPX培地(キシロース:20g/L)200mlが入った500ml三角フラスコで、30℃、140rpm、一晩振とう培養した。培養後の酵母を遠心回収、滅菌水で3回洗浄し、OD600=30の酵母懸濁液を調製した。
Pre-culture
One platinum loop of the disrupted strain was inoculated into a 50 ml assist tube to which 20 ml of YPX (xylose 20 g / L) medium was added, and cultured with shaking at 30 ° C. and 140 rpm for 6 to 8 hours. Next, 2.5% of the bacterial solution was cultured overnight in a 500 ml Erlenmeyer flask containing 200 ml of YPX medium (xylose: 20 g / L) at 30 ° C. and 140 rpm. The cultured yeast was collected by centrifugation and washed three times with sterilized water to prepare a yeast suspension with OD600 = 30.
本培養
表5に示す条件で培養し、エタノール生産を確認した。初発の糖濃度は、キシロース20g/Lとした。
Culture was performed under the conditions shown in Table 5 to confirm ethanol production. The initial sugar concentration was 20 g / L xylose.
また、培地中のエタノール濃度は島津製作所社製のHPLC(検出器:RI)を用いて測定した。 The ethanol concentration in the medium was measured using HPLC (detector: RI) manufactured by Shimadzu Corporation.
<結果>
糖成分としてキシロースを含有する培地にて上記破壊株を培養した際の「培地中のエタノール収率」を図1に示す。図1に示すように、ほとんどの各遺伝子破壊株では、野生株(DMKU3-1042株)と比較し、キシロースからのエタノール収率が1.9〜2.5倍に向上していた。
<Result>
“Ethanol yield in the medium” when the disrupted strain is cultured in a medium containing xylose as a sugar component is shown in FIG. As shown in FIG. 1, in each of the gene disrupted strains, the ethanol yield from xylose was improved by 1.9 to 2.5 times compared to the wild strain (DMKU3-1042 strain).
Claims (4)
(a)前記MET8遺伝子又はその機能的に等価な遺伝子が、配列番号4記載のアミノ酸配列を含むタンパク質、又は配列番号4記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、且つ二機能性デヒドロゲナーゼ及びフェロケラターゼ活性を有するタンパク質をコードする遺伝子であり、
(b)前記MTVK879遺伝子又はその機能的に等価な遺伝子が、配列番号6記載のアミノ酸配列を含むタンパク質、又は配列番号6記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、且つL-キシルロースレダクターゼ活性を有するタンパク質をコードする遺伝子であり、
(c)前記MSSS1716遺伝子又はその機能的に等価な遺伝子が、配列番号8記載のアミノ酸配列を含むタンパク質、又は配列番号8記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、且つキシリトールトランスポーター活性を有するタンパク質をコードする遺伝子であり、
(d)前記YJR008W遺伝子又はその機能的に等価な遺伝子が、配列番号10記載のアミノ酸配列を含むタンパク質、又は配列番号10記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(e)前記MSIN612遺伝子又はその機能的に等価な遺伝子が、配列番号12記載のアミノ酸配列を含むタンパク質、又は配列番号12記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(f)前記MVNT843遺伝子又はその機能的に等価な遺伝子が、配列番号14記載のアミノ酸配列を含むタンパク質、又は配列番号14記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含み、且つL-キシルロースレダクターゼ活性を有するタンパク質をコードする遺伝子であり、
(g)前記MSEI528遺伝子又はその機能的に等価な遺伝子が、配列番号16記載のアミノ酸配列を含むタンパク質、又は配列番号16記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(h)前記MAMI1389遺伝子又はその機能的に等価な遺伝子が、配列番号18記載のアミノ酸配列を含むタンパク質、又は配列番号18記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(i)前記YAL004W遺伝子又はその機能的に等価な遺伝子が、配列番号20記載のアミノ酸配列を含むタンパク質、又は配列番号20記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(j)前記MLKP1164遺伝子又はその機能的に等価な遺伝子が、配列番号22記載のアミノ酸配列を含むタンパク質、又は配列番号22記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(k)前記MTEG777遺伝子又はその機能的に等価な遺伝子が、配列番号24記載のアミノ酸配列を含むタンパク質、又は配列番号24記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子であり、
(l)前記MQFK915遺伝子又はその機能的に等価な遺伝子が、配列番号26記載のアミノ酸配列を含むタンパク質、又は配列番号26記載のアミノ酸配列に対して90%以上の配列同一性を有するアミノ酸配列を含むタンパク質をコードする遺伝子である、
前記変異体酵母。 When using xylose as a substrate, a mutant yeast in which a gene that is highly expressed as compared to when using glucose is attenuated , wherein the mutant yeast is a yeast belonging to the genus Kluyveromyces, and the gene is , MET8 gene, MTVK879 gene, MSSS1716 gene, YJR008W gene, MSIN612 gene, MVNT843 gene, MSEI528 gene, MAMI1389 gene, YAL004W gene, MLKP1164 gene, MTEG777 gene and MQFK915 gene and a group functionally equivalent to these genes At least one gene selected from
(a) the MET8 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 4 or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 4 A gene encoding a protein comprising and having bifunctional dehydrogenase and ferrochelatase activity,
(b) the MTVK879 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence of SEQ ID NO: 6 or an amino acid sequence having a sequence identity of 90% or more with respect to the amino acid sequence of SEQ ID NO: 6 And a gene encoding a protein having L-xylulose reductase activity,
(c) the MSSS1716 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 8, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 8 And a gene encoding a protein having xylitol transporter activity,
(d) the YJR008W gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 10, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 10. A gene encoding a protein containing,
(e) the MSIN612 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 12, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 12. A gene encoding a protein containing,
(f) the MVNT843 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 14 or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 14 And a gene encoding a protein having L-xylulose reductase activity,
(g) the MSEI528 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 16 or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 16 A gene encoding a protein containing,
(h) the MAMI1389 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 18, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 18. A gene encoding a protein containing,
(i) the YAL004W gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 20, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 20 A gene encoding a protein containing,
(j) the MLKP1164 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 22, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 22 A gene encoding a protein containing,
(k) the MTEG777 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence set forth in SEQ ID NO: 24, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence set forth in SEQ ID NO: 24 A gene encoding a protein containing,
(l) the MQFK915 gene or a functionally equivalent gene thereof is a protein comprising the amino acid sequence of SEQ ID NO: 26, or an amino acid sequence having 90% or more sequence identity to the amino acid sequence of SEQ ID NO: 26 A gene encoding a protein containing,
The mutant yeast .
その後、培地よりエタノールを回収する工程と、
を含む、エタノールの製造方法。 Culturing the mutant yeast according to claim 1 or 2 in a xylose-containing medium;
Then, recovering ethanol from the medium;
A method for producing ethanol, comprising:
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