宿主遗传背景对重组酿酒酵母木糖共发酵影响的研究进展

木糖是纤维素原料水解液中最主要的五碳糖成分,由于野生的酿酒酵母缺乏有效的木糖利用途径,将外源木糖代谢途径整合至酿酒酵母中使其具有发酵木糖生产乙醇的能力是构建纤维素乙醇发酵菌株的关键。国内外学者的研究表明,同一木糖代谢途径导入不同酿酒酵母菌株中,所得到的重组菌发酵性能存在明显差异,表明宿主的遗传背景对菌株利用木糖能力和发酵性能具有重要的影响。就酿酒酵母宿主对重组菌株的木糖发酵性能的影响进行了综述,分析了产生宿主差异的内在机理,为进一步选育高效木糖共发酵菌种提供借鉴。     

系列过表达非氧化磷酸戊糖途径基因对重组酿酒酵母菌株木糖代谢的影响

【目的】通过系统研究一个、两个及多个非氧化磷酸戊糖(PP)途径基因组合过表达对酿酒酵母木糖代谢的影响,以优化重组菌株的构建过程,构建高效的木糖代谢酿酒酵母菌株。【方法】在酿酒酵母中双拷贝过表达上游代谢途径的关键酶(木糖还原酶XR,木糖醇脱氢酶XDH,木酮糖激酶XKS),在此基础上构建了一系列PP途径基因过表达菌株,并对其木糖发酵性能进行比较研究。【结果】木糖发酵结果显示,不同组合过表达PP途径基因能不同程度改善重组菌株的木糖发酵性能。其中,过表达PP途径全部基因(RKI1,RPE1,TAL1和TKL1)使菌株的发酵性能最优,其乙醇产率和产量较对照菌株分别提高了39.25%和12.57%,同时较其他基因组合过表达菌株也有不同程度的改善。【结论】通过构建PP途径基因不同组合过表达酿酒酵母菌株,首次对PP途径基因对酿酒酵母木糖代谢的影响进行了系统研究,结果表明,不同组合强化PP途径基因对重组菌株木糖代谢的影响存在差异,相对于其他基因过表达组合,同步过表达PP途径全部基因最有利于碳通量流向乙醇。     

混合糖发酵重组酿酒酵母的菌株构建和菊芋秸秆同步糖化发酵研究

【目的】构建可用于纤维素乙醇高效生产的混合糖发酵重组酿酒酵母菌株,并利用菊芋秸秆为原料进行乙醇发酵。【方法】筛选在木糖中生长较好的酿酒酵母YB-2625作为宿主菌,构建木糖共代谢菌株YB-2625 CCX。进一步通过r DNA位点多拷贝整合的方式,以YB-2625 CCX为出发菌株构建木糖脱氢酶过表达菌株,并筛选得到优势菌株YB-73。采用同步糖化发酵策略研究YB-73的菊芋秸秆发酵性能。【结果】YB-73菌株以90 g/L葡萄糖和30 g/L木糖为碳源进行混合糖发酵,乙醇产量比出发菌株YB-2625 CCX提高了13.9%,副产物木糖醇产率由0.89 g/g降低至0.31 g/g,下降了64.6%。利用重组菌YB-73对菊芋秸秆进行同步糖化发酵,48 h最高乙醇浓度达到6.10%(体积比)。【结论】通过转入木糖代谢途径以及r DNA位点多拷贝整合过表达木糖脱氢酶基因可有效提高菌株木糖发酵性能,并用于菊芋秸秆的纤维素乙醇生产。这是首次报道利用重组酿酒酵母进行菊芋秸秆原料的纤维素乙醇发酵。     

利用不同启动子控制木糖代谢关键酶基因构建可共代谢葡萄糖木糖重组酿酒酵母

利用不同强度的启动子调控木糖代谢关键酶活性,构建稳定代谢葡萄糖和木糖产乙醇的重组酿酒酵母。以本实验室专利菌株Saccharomyces cerevisiae Y5为宿主菌,将树干毕赤酵母Pichia stipitis CBS6054的木糖还原酶基因XYL1和木糖醇脱氢酶基因XYL2置于磷酸甘油酸激酶基因启动子(PGKp)控制下,酿酒酵母Y5内源的木酮糖激酶基因XKS1分别由己糖激酶基因启动子(HXK2p)及其内源启动子(XKS1p)控制。这3个基因连同各自表达元件导入宿主细胞中,打通其木糖上游代谢途径。酶活测定结果显示,HXK2p对木酮糖激酶表现出更强的启动效率。重组菌Y5-X3-1中木糖还原酶/木糖醇脱氢酶/木酮糖激酶(XR/XDH/XK)的酶活比值为1∶5∶4,其木糖消耗量是宿主菌的5倍,最高乙醇产量为24.35 g/L,达到理论值的73%。结果表明,通过调节XYL1、XYL2及XKS1启动子的强度,调控其表达水平,进而改变3种酶的活性水平,对于提高重组酿酒酵母利用木糖发酵产乙醇有明显效果。     

木酮糖激酶基因整合表达载体构建及在酿酒酵母中的过表达

【目的】以载体p406ADH1为构建骨架,构建一个酿酒酵母(Saccharomyces cerevisiae)工业菌株的整合表达载体。【方法】通过酶切连接的方式,将4个元件片段:作为筛选标记的G418抗性基因KanR,用于基因表达的ADH1终止子片段,酿酒酵母W5自身木酮糖激酶基因,18S rDNA介导的同源整合区,插入到骨架质粒p406ADH1中,得到多拷贝整合表达载体pCXS-RKTr。将该载体线性转化酿酒酵母后,对转化子中木酮糖激酶酶活进行测定,检测其表达情况。【结果】重组质粒在酿酒酵母体内实现了木酮糖激酶的高水平稳定表达,其酶活力是初始菌株的2.87倍。【结论】本实验构建了一个酿酒酵母工业菌株整合表达载体,并用此载体过表达了其自身的木酮糖激酶基因。该重组质粒载体的构建可以有效解决酿酒酵母中自身木酮糖激酶酶活较低的情况,这为利用木糖高产乙醇酿酒酵母基因工程菌株的构建和其它酵母重组质粒载体的构建奠定基础。     

异源表达木糖异构酶基因对克雷伯氏菌合成1,3-丙二醇的影响

【目的】提高克雷伯氏菌胞内还原力以强化1,3-丙二醇合成。【方法】将来源于大肠杆菌的木糖异构酶基因在克雷伯氏菌中异源表达,构建重组菌。研究重组菌添加不同浓度木糖为辅底物与甘油共发酵过程中代谢产物和NADH的变化规律。【结果】与对照菌相比,重组菌细胞内还原力NADH提高了0.1?0.3倍,1,3-丙二醇产量达到23.31 g/L,提高20%,1,3-丙二醇转化率从0.60 mol/mol提高到0.73 mol/mol。【结论】木糖异构酶基因的表达强化了木糖代谢途径,经磷酸戊糖途径积累大量还原力,促进了1,3-丙二醇的生成。     

四川甘孜州高山葡萄酒产区酵母菌多样性分析

【背景】西南高山葡萄酒产区的甘孜州产区,具有生产优质葡萄酒的自然禀赋。【目的】研究四川甘孜州葡萄酒产区真核微生物种类多样性、本土酿酒酵母遗传多样性,以及商业酵母对本土酵母多样性的影响。【方法】利用ITS高通量测序技术对赤霞珠接种发酵和自然发酵过程中的微生物进行多样性分析,并利用Interdelta指纹图谱分析法,对经过26S rRNA基因鉴定的野生酿酒酵母基因型进行分类。【结果】ITS测序结果显示,接种发酵和自然发酵各时期均注释到7个科7个属的酵母,通过Interdelta指纹图谱分析发现甘孜州产区的酿酒酵母共有5种基因型。该产区酿酒酵母的6株代表菌株与我国其他产区109株酿酒酵母的进化树分析结果显示,均与来自北京产区的酿酒酵母菌株亲缘关系更近。【结论】甘孜州葡萄酒子产区酵母资源丰富,表现出较高的微生物多样性和中等程度的本土酿酒酵母基因型多样性,为后续优良本土酵母菌株的筛选奠定基础。     

克隆木糖还原酶XYL1基因的工程菌YT发酵玉米芯水解液的研究

克隆毕赤氏酵母(Pichia stipitis)木糖还原酶基因XYL1,将其连接到适用于酿酒酵母工业菌株的多拷贝载体pYMIKP中,构建得到表达质粒pYMIKY-XYL1,转化酿酒酵母工业菌株Saccharomyces cerevisiae 6508.利用G418筛选转化子,得到含高拷贝木糖还原酶基因的酿酒酵母重组菌YT,以YT发酵玉米芯工业水解液生产木糖醇,研究其发酵特性和规律,为工业上生物转化法生产木糖醇提供参考.     

代谢工程改造热带假丝酵母生产1,2,4-丁三醇

【背景】 1,2,4-丁三醇属于手性多羟基醇,是一种重要的有机合成的化学中间体,以木糖为原料经四步酶反应是目前研究最多的生物合成路线。然而大肠杆菌的鲁棒性较弱,对发酵液中一些抑制剂的耐受性不是很好,同时存在严重的碳代谢抑制。近年来,鲁棒性较好的酵母菌成为更有吸引力的宿主,其中热带假丝酵母具有天然的木糖代谢途径,可以更好地利用木糖。【目的】在热带假丝酵母中构建从木糖到1,2,4-丁三醇的代谢途径。【方法】在热带假丝酵母中敲除木糖还原酶基因GRE3,从而阻断自身的木糖代谢途径。将来源于Caulobacter crescentus的木糖脱氢酶基因(xylB)和木糖酸脱水酶基因(xylD)及来源于Lactococcus lactis的酮酸脱羧酶基因(kdcA)克隆至C. tropicalis 207中,得到重组菌C. tropicalis BT,在此基础上考察重组菌代谢木糖合成1,2,4-丁三醇的能力,确定限速步骤,并通过增加关键基因xylD与kdcA的拷贝数提高1,2,4-丁三醇产量。【结果】在30℃、200 r/min、接种量1%、以30 g/L木糖为底物的情况下,重组菌的1,2,4-丁三醇的产量达到了1.2 g/L,在5 L发酵罐中的产量达到了3.7 g/L。【结论】在热带假丝酵母中实现以木糖为底物的1,2,4-丁三醇代谢途径,并通过在基因组上增加关键基因xylD与kdcA的拷贝数,获得了一株高产1,2,4-丁三醇的重组酵母菌株,这为后续在热带假丝酵母中进一步提高1,2,4-丁三醇产量奠定了基础。     

稳定遗传的染色体组合整合酿酒酵母重组菌株的构建

染色体整合表达可获得稳定遗传的基因工程菌,是工业酿酒酵母育种的重要手段。pAUR135整合载体是抗生素标记基因可循环使用的载体,添加特定的同源臂后可构建在酵母染色体上稳定遗传的菌株。目前对酵母菌的分子育种常需要对多个基因进行过表达,利用pAUR135载体可将不同基因分别整合在不同染色体或相同染色体的不同位点,这种组合整合表达方法可对不同基因的表达强度比例进行调节,构建表型优化的工业酿酒酵母菌株。本研究以木糖代谢途径基因为例,构建了3个pAUR135整合载体,将3个木糖代谢基因依次整合到工业酿酒酵母染色体的不同位点,获得了染色体组合整合表达的代谢工程菌株。与将这3个基因整合在同一个位点的对照重组菌株相比,染色体组合整合的重组菌株木糖利用率提高了24.4%–35.5%。多基因染色体组合整合方法从新的角度对工业酵母进行代谢工程改造,所获得的工程菌株不带有任何外来基因和选择标记,可以保持性状的稳定,是工业酿酒酵母分子育种的新方法。     

Overexpression of bacterial xylose isomerase and yeast host xylulokinase improves xylose alcoholic fermentation in the thermotolerant yeast Hansenula polymorpha

The thermotolerant methylotrophic yeast Hansenula polymorpha is able to ferment xylose to ethanol. To improve characteristics of xylose fermentation, the recombinant strain Delta xyl1 Delta xyl2-ADelta xyl2-B, with deletions of genes encoding first enzymes of xylose utilization (NAD(P)H-dependent xylose reductase and NAD-dependent xylitol dehydrogenases, respectively), was constructed and used as a recipient for co-overexpression of the Escherichia coli xylA gene coding for xylose isomerase and endogenous XYL3 gene coding for xylulokinase. The expression of both genes was driven by the H. polymorpha glyceraldehyde-3-phosphate dehydrogenase promoter. Xylose isomerase activities of obtained transformants amounted to approximately 80% of that of the bacterial host strain. Xylulokinase activities of the transformants increased twofold when compared with the parental strain. The recombinant strains displayed improved ethanol production during the fermentation of xylose.     

Comparative study on a series of recombinant flocculent Saccharomyces cerevisiae strains with different expression levels of xylose reductase and xylulokinase

Ethanol production from xylose is important for the utilization of lignocellulosic biomass as raw materials. Recently, we reported the development of an industrial xylose-fermenting Saccharomyces cerevisiae strain, MA-R4, which was engineered by chromosomal integration to express the genes encoding xylose reductase and xylitol dehydrogenase from Pichia stipitis along with S. cerevisiae xylulokinase gene constitutively using the alcohol-fermenting flocculent yeast strain, IR-2. IR-2 has the highest xylulose-fermenting ability of the industrial diploid strains, making it a useful host strain for genetically engineering xylose-utilizing S. cerevisiae. To optimize the activities of xylose metabolizing enzymes in the metabolic engineering of IR-2 for further improvement of ethanol production from xylose, we constructed a set of recombinant isogenic strains harboring different combinations of genetic modifications present in MA-R4, and investigated the effect of constitutive expression of xylulokinase and of different levels of xylulokinase and xylose reductase activity on xylose fermentation. This strain comparison showed that constitutive expression of xylulokinase increased ethanol production from xylose at the expense of xylitol excretion, and that high activity of xylose reductase resulted in an increased rate of xylose consumption and an increased glycerol yield. Moreover, strain MA-R6, which has moderate xylulokinase activity, grew slightly better but accumulated more xylitol than strain MA-R4. These results suggest that fine-tuning of introduced enzyme activity in S. cerevisiae is important for improving xylose fermentation to ethanol.     

An improved method of xylose utilization by recombinant Saccharomyces cerevisiae

The aim of this study was to develop a method to optimize expression levels of xylose-metabolizing enzymes to improve xylose utilization capacity of Saccharomyces cerevisiae. A xylose-utilizing recombinant S. cerevisiae strain YY2KL, able to express nicotinamide adenine dinucleotide phosphate, reduced (NADPH)-dependent xylose reductase (XR), nicotinamide adenine dinucleotide (NAD(+))-dependent xylitol dehydrogenase (XDH), and xylulokinase (XK), showed a low ethanol yield and sugar consumption rate. To optimize xylose utilization by YY2KL, a recombinant expression plasmid containing the XR gene was transformed and integrated into the aur1 site of YY2KL. Two recombinant expression plasmids containing an nicotinamide adenine dinucleotide phosphate (NADP(+))-dependent XDH mutant and XK genes were dually transformed and integrated into the 5S ribosomal DNA (rDNA) sites of YY2KL. This procedure allowed systematic construction of an S. cerevisiae library with different ratios of genes for xylose-metabolizing enzymes, and well-grown colonies with different xylose fermentation capacities could be further selected in yeast protein extract (YPX) medium (1?% yeast extract, 2?% peptone, and 2?% xylose). We successfully isolated a recombinant strain with a superior xylose fermentation capacity and designated it as strain YY5A. The xylose consumption rate for strain YY5A was estimated to be 2.32?g/gDCW/h (g xylose/g dry cell weight/h), which was 2.34 times higher than that for the parent strain YY2KL (0.99?g/gDCW/h). The ethanol yield was also enhanced 1.83 times by this novel method. Optimal ratio and expression levels of xylose-metabolizing enzymes are important for efficient conversion of xylose to ethanol. This study provides a novel method that allows rapid and effective selection of ratio-optimized xylose-utilizing yeast strains. This method may be applicable to other multienzyme systems in yeast.     

高氨氮利用酵母菌的筛选及相关酶活性

【背景】蛋白饲料的缺乏,促进了蛋白含量高、安全性能好的酵母类单细胞蛋白的研究与应用。【目的】筛选氨氮利用能力强的菌株,为单细胞蛋白的发酵提供优良菌株。【方法】从土壤、奶制品、水果采集样品分离酵母菌,根据形态学和分子生物学鉴定菌株,然后以硫酸铵为唯一氮源培养基,测定菌落大小、菌体干重、蛋白质含量,复筛氨氮利用率高的酵母菌,并对复筛菌株氨同化相关酶活性进行测定。【结果】经过形态学、分子生物学鉴定和氨氮利用能力评价,获得3株高氨氮利用的酵母菌,分别是胶红酵母(Rhodotorula mucilaginosa)、酿酒酵母(Saccharomyces cerevisiae)和戴尔有孢圆酵母(Torulaspora delbrueckii)。通过比较3株酵母菌的谷氨酸脱氢酶、谷氨酸合成酶、谷氨酰胺合成酶活性,酿酒酵母的3种酶活性最高,其次是胶红酵母。【结论】从奶酪和西瓜中分离的胶红酵母N5和酿酒酵母J1具有较强的氨氮利用能力以及酶活性,可为单细胞蛋白发酵提供优良菌株。     

转醛醇酶基因差异表达影响酵母发酵木糖及耐受乙酸性能

【目的】木糖发酵是纤维素燃料乙醇生产的一个关键瓶颈,同时木质纤维素水解液中的乙酸严重抑制酿酒酵母的木糖发酵过程,因此通过基因工程手段提高菌株对木糖的利用以及对乙酸的耐受性具有重要意义。本研究以非氧化磷酸戊糖途径(PPP途径)中关键基因转醛醇酶基因(TAL1)为研究对象,探讨了3种不同启动子PTDH3、PAHP1和PUBI4,控制其表达对菌株利用木糖和耐受乙酸的影响。【方法】通过同源重组用3种启动子替换酿酒酵母基因工程菌NAPX37的TAL1基因的启动子PTAL1,再通过孢子分离和单倍体交配构建了纯合子,利用批次发酵比较了在以木糖为唯一碳源和混合糖(葡萄糖和木糖)为碳源条件下,3种启动子控制TAL1基因表达导致的发酵和乙酸耐受能力的差异。【结果】启动子PTDH3、PAHP1和PUBI4在不同程度上提高了TAL1基因的转录水平,提高了菌株对木糖的利用速率及乙酸耐受能力,提高了菌株在60 mmol/L乙酸条件下的葡萄糖利用速率。在以木糖为唯一碳源且无乙酸存在、以及混合糖为碳源的条件下,PAHP1启动子控制TAL1表达菌株的发酵结果优于PTDH3和PUBI4启动子的菌株,PAHP1启动子控制的TAL1基因的转录水平比较合适。在木糖为唯一碳源且乙酸为30 mmol/L时,PUBI4启动子控制TAL1基因表达的菌株发酵结果则优于PAHP1和PTDH3启动子菌株,此时PUBI4启动子控制的TAL1的转录水平比较合适。【结论】启动子PTDH3、PAHP1和PUBI4不同程度地提高TAL1基因的表达,在不同程度上改善了酵母菌株的木糖发酵速率和耐受乙酸性能,改善程度受发酵条件的影响。     

Effect of glucose on xylose utilization in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> harboring the xylose reductase gene

We have constructed recombinant Saccharomyces cerevisiae JH1 harboring a xylose reductase gene (xyl1) isolated from Pichia stipitis. However, JH1 still utilizes glucose more easily than xylose. Therefore, in this study, we characterized the effect of a glucose supplement on xylose utilization, the expression level of xylose reductase as a recombinant gene in JH1, and the expression levels of two hexose transporters (Hxt4 and Hxt7) due to co-fermentation of different concentrations of glucose and xylose. Co-fermentation using 20 g/l of glucose increased xylose consumption up to 11.7 g/l, which was 7.9-fold that of xylose fermentation without a glucose supplement. In addition, we found xyl1 mRNA levels dramatically increased as cells grew under co-fermentation conditions with supplementary glucose; this result is consistent with a significant decrease in the xylose concentration 48 h after cultivation. In addition, the expression levels of Hxt4 and Hxt7 were strongly activated by the presence of glucose and xylose; in particular, Hxt7 showed a 2.9-fold increased expression relative to that of recombinant S. cerevisiae JHM with only a backbone vector, pYES2. The results of this study suggest that xylose utilization would be improved by activation of hexose transporters induced by glucose (rather than xylose) reductase expression.     

Expression of bifunctional enzymes with xylose reductase and xylitol dehydrogenase activity in Saccharomyces cerevisiae alters product formation during xylose fermentation.

To enhance metabolite transfer in the two initial sequential steps of xylose metabolism in yeast, two structural genes of Pichia stipitis, XYL1 and XYL2 encoding xylose reductase (XR) and xylitol dehydrogenase (XDH), respectively, were fused in frame. Four chimeric genes were constructed, encoding fusion proteins with different orders of the enzymes and different linker lengths. These genes were expressed in Saccharomyces cerevisiae. The fusion proteins exhibited both XR and XDH activity when XYL1 was fused downstream of XYL2. The specific activity of the XDH part of the complexes increased when longer peptide linkers were used. Bifunctional enzyme complexes, analyzed by gel filtration, were found to be tetramers, hexamers, and octamers. No degradation products were detected by Western blot analysis. S. cerevisiae strains harboring the bifunctional enzymes grew on minimal-medium xylose plates, and oxygen-limited xylose fermentation resulted in xylose consumption and ethanol formation. When a fusion protein, containing a linker of three amino acids, was coexpressed with native XR and XDH monomers in S. cerevisiae, enzyme complexes consisting of chimerical and native subunits were formed. The total activity of these complexes showed XR and XDH activities similar to the activities obtained when the monomers were expressed individually. Strains which coexpressed chimerical subunits together with native XR and XDH monomers consumed less xylose and produced less xylitol. However, the xylitol yield was lower in these strains than in strains expressing only native XR and XDH monomers, 0.55 and 0.62, respectively, and the ethanol yield was higher. The reduced xylitol yield was accompanied by reduced glycerol and acetate formation suggesting enhanced utilization of NADH in the XR reaction.