MRP8过表达促进重组酿酒酵母外切纤维素酶生产

增强酿酒酵母纤维素酶分泌能力,为提高利用联合生物加工生产纤维素乙醇的效率提供基础。采用CRISPR/Cas9基因组编辑技术,在分泌表达外切纤维素酶CBH1的酿酒酵母Y294中过表达线粒体核糖体蛋白基因MRP8。与对照菌株相比,过表达MRP8重组酵母的胞外CBH1酶活提高了约80%。实时定量PCR结果分析表明,在MRP8过表达突变体中,CBH1转录水平高于对照菌株,但是与蛋白折叠和分泌相关的关键基因转录水平没有明显变化。在刚果红平板和含有衣霉素或二硫苏糖醇的平板上生长没有受到影响。胞内ATP含量和活性氧积累未发现显著差别。本研究表明MRP8过表达促进外切纤维素酶的生产。     

破坏细胞壁蛋白CWP2基因提高重组酿酒酵母β-葡萄糖苷酶胞外酶活

【背景】重组酿酒酵母广泛应用于生产工业酶和药用蛋白,但是目前仍旧存在异源蛋白产量低、分泌效率差的问题,限制了生产应用。【目的】提高重组酿酒酵母异源分泌蛋白的能力,构建高效的异源蛋白生产细胞工厂。【方法】采用基于CRISPR/Cas9的基因组编辑技术,以生产β-葡萄糖苷酶的重组酿酒酵母Y294-BGL为出发菌株,构建细胞壁蛋白基因CWP2破坏菌株。【结果】与出发菌株相比,破坏CWP2的破坏菌株在发酵96 h时胞外β-葡萄糖苷酶酶活可提高53%,胞内酶活提高了208%。此外,破坏菌生长未受到影响,对弱酸等环境胁迫的耐性没有下降,未造成过多内质网胁迫。进一步检测发现,破坏菌株胞内活性氧水平下降,同时蛋白胞内运输和分泌途径相关的关键基因表达转录及多个细胞壁生物合成相关基因表达下降。【结论】破坏细胞壁蛋白基因CWP2能够提高异源蛋白β-葡萄糖苷酶的胞外酶活,可作为促进酿酒酵母生产异源蛋白的靶点基因。     

UTH1基因破坏提高重组酿酒酵母分泌β-葡萄糖苷酶

异源蛋白质分泌效率低限制了重组酿酒酵母的多种药用蛋白和工业酶生产。挖掘促进蛋白质生物合成和分泌的关键基因,是提高异源蛋白质生产效率的重要手段。酿酒酵母细胞壁完整性影响异源蛋白质分泌,本研究利用基于CRISPR/Cas9的基因组编辑技术,破坏了重组酿酒酵母Y294-BGL1中参与细胞壁合成的未知功能基因UTH1,发现所获得的突变体胞外β-葡萄糖苷酶酶活比出发菌株提高112.9%,而细胞壁完整性下降。对促进产酶的分子机理进行探索,发现突变体产酶条件下与细胞壁完整性相关的关键基因和与蛋白质分泌途径相关的基因转录出现明显差异,提示UTH1基因破坏不仅影响细胞壁完整性关键基因的表达,也影响蛋白质分泌途径。本文的研究结果有助于深入理解UTH1的基因功能,并为构建异源蛋白质高分泌酵母菌株提供了借鉴。     

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。     

里氏木霉翻转酶DRS2对木质纤维素降解酶基因表达及分泌的影响

【目的】本研究以工业生产菌株里氏木霉为研究对象,鉴定翻转酶基因drs2对其纤维素酶表达及分泌的影响。【方法】首先通过BLAST序列比对,从里氏木霉中鉴定出翻转酶基因drs2,并通过同源重组的方法在里氏木霉中构建了drs2基因的敲除菌株△drs2。对△drs2菌株及其对照株在不同碳源上的生长发育、蛋白分泌、纤维素酶及半纤维素酶的表达水平等进行比较分析,并对DSR2蛋白进行了亚细胞定位。【结果】与对照菌株Cpyr4相比,△drs2菌株在葡萄糖、乳糖、微晶纤维素(avicel)等条件下生长速率都明显降低。△drs2菌株在纤维素诱导条件下的总蛋白分泌量、纤维素酶活力、半纤维素酶活力均显著提高,但drs2基因的缺失并不影响关键纤维素酶基因的转录水平。DRS2蛋白位于里氏木霉菌丝近顶端的顶体位置。【结论】在纤维素为唯一碳源的条件下,drs2基因的缺失导致纤维素酶的产量显著提高,drs2基因不调控纤维素酶基因的转录,而是在其分泌过程中发挥作用。     

产肌醇酿酒酵母基因工程菌的构建

【目的】过表达酿酒酵母肌醇合成关键酶基因INO1,促进肌醇合成,构建能够分泌肌醇的基因工程菌株。【方法】构建r DNA介导的INO1基因多拷贝整合表达载体p URIH,电转化酿酒酵母Y01菌株,构建工程菌株YI2-1和YI2-2,荧光定量PCR方法分析INO1基因表达量。敲除Kan MX抗性基因,HPLC检测重组菌发酵液中肌醇含量。【结果】获得INO1基因过表达菌株YI2-1和YI2-2,YI2-1的INO1基因表达量是出发菌Y01的16.235倍。敲除Kan MX抗性基因的菌株命名为YI2-1△KP,初步检测YI2-1△KP产肌醇量为627 mg/L。【结论】r DNA介导的INO1基因多拷贝整合表达载体p URIH能够有效地过表达目的基因;过表达菌株合成的肌醇不仅能满足自身的需要,而且能够向胞外分泌,具有潜在的工业应用价值。     

一株降解纤维素放线菌的产纤维素酶基因克隆与表达

【背景】纤维素在自然界中储量丰富,但天然纤维素的难降解性成为广泛应用纤维素资源的壁垒,近年来利用微生物来降解纤维素成为热点研究。【目的】筛选分离得到一株具有降解纤维素功能的放线菌菌株Lb1,通过全基因组测序确定其产纤维素酶关键基因5676,对基因5676进行克隆转化,使其在大肠杆菌中进行表达。【方法】通过基因工程技术将产纤维素基因连接到表达质粒上并导入表达菌株,对其降解纤维素生成葡萄糖的能力进行探究。【结果】将Lb1菌株的16S rRNA基因进行比对,确定菌株Lb1属于链霉菌属,命名为Streptomyces sp. Lb1。成功构建出纤维素酶表达载体,并且导入表达菌株大肠杆菌BL21(DE3),重组菌株的产纤维素酶能力大于空载菌株。【结论】通过基因工程技术成功克隆出产纤维素酶基因,从而表达纤维素酶,为今后利用微生物降解纤维素的大规模应用提供参考。     

斜卧青霉转录调控因子BglR的缺失对纤维素酶生产的影响

【目的】斜卧青霉(Penicillium decumbens)作为高效分泌纤维素酶的重要丝状真菌,其纤维素酶的合成与分泌在转录水平上被调控。进一步研究纤维素酶基因表达的转录调控,构建高效高产纤维素酶的工业菌株。【方法】根据斜卧青霉114-2在不同碳源生长条件下基因组表达谱的差异,发现新的转录调控因子BglR(PDE-01706),该蛋白与产黄青霉(Penicillium chrysogenum)Pc20g04780的锌指结构蛋白具有59%同源性。通过基因同源双交换,得到BglR缺失突变株ΔbglR-1,对突变株ΔbglR-1的表型、营养生长、产纤维素酶活、蛋白分泌能力及发酵液pH变化进行研究。【结果】转录调控因子BglR的缺失可导致突变株ΔbglR-1的β-葡萄糖苷酶活力提高40%,并造成其滤纸酶活、内切葡聚糖酶及木聚糖酶活明显降低。【结论】结果表明转录调控因子BglR对于斜卧青霉纤维素酶的调控有重要作用。     

代谢工程改造酿酒酵母合成肌醇

【目的】肌醇别名环己六醇,是一种具有生物活性的糖醇,在医药、食品和饲料等领域具有重要的应用价值。为获得生产肌醇的微生物细胞工厂,通过代谢工程改造,构建生产肌醇的酿酒酵母工程菌株。【方法】对酿酒酵母肌醇合成途径的正负调控同时改造,过表达肌醇-3-磷酸合成酶基因ino1,敲除肌醇生物合成的转录抑制子基因opi1和抗性基因kan MX,获得重组菌。利用气相色谱法检测重组菌发酵液中肌醇含量。【结果】构建了生物安全性的产肌醇基因工程菌株,摇瓶培养产量为1.021 g/L。【结论】通过过表达ino1和敲除opi1来改造酿酒酵母,能够有效提高重组菌的肌醇产量,为下一步的微生物发酵法产肌醇的工业应用奠定基础。     

双孢蘑菇酪氨酸酶基因在酿酒酵母中的异源表达及其酶学特性

【目的】在酿酒酵母中异源表达双孢蘑菇来源的酪氨酸酶基因PPO2,并研究酪氨酸酶在酿酒酵母胞内及胞外的酶学特性。【方法】提取双孢蘑菇总RNA,通过RT-PCR克隆酪氨酸酶基因PPO2,构建表达载体pSP-G1-PPO2,并转化至酿酒酵母进行表达,采用镍亲和层析纯化蛋白并研究其酶学性质。【结果】在酿酒酵母中正确表达了大小为65 kDa的酪氨酸酶蛋白。重组酶能催化底物酪氨酸产生黑色素。体外活性测定表明,酪氨酸酶催化最适温度为45°C,以酪氨酸和多巴为底物时最适pH分别为7.0和8.0。在酿酒酵母中测得底物酪氨酸浓度低于2.5 mg/mL时,黑色素的产量与底物浓度呈现正相关性。【结论】来源于双孢蘑菇的酪氨酸酶基因PPO2在酿酒酵母中成功表达,重组酶具有良好的酶学特性。利用酪氨酸酶产物黑色素的产量与底物浓度呈现正相关性这一特性,可将其作为细胞酪氨酸产量的传感器,为高通量筛选酪氨酸高产菌株提供了思路。     

The metabolic burden of cellulase expression by recombinant Saccharomyces cerevisiae Y294 in aerobic batch culture

Two recombinant strains of Saccharomyces cerevisiae Y294 producing cellulase using different expression strategies were compared to a reference strain in aerobic culture to evaluate the potential metabolic burden that cellulase expression imposed on the yeast metabolism. In a chemically defined mineral medium with glucose as carbon source, S. cerevisiae strain Y294[CEL5] with plasmid-borne cellulase genes produced endoglucanase and β-glucosidase activities of 0.038 and 0.30 U mg dry cell weight(-1), respectively. Chromosomal expression of these two cellulases in strain Y294[Y118p] resulted in no detectable activity, although low levels of episomally co-expressed cellobiohydrolase (CBH) activity were detected. Whereas the biomass concentration of strain Y294[CEL5] was slightly greater than that of a reference strain, CBH expression by Y294[Y118p] resulted in a 1.4-fold lower maximum specific growth rate than that of the reference. Supplementation of the growth medium with amino acids significantly improved culture growth and enzyme production, but only partially mitigated the physiological effects and metabolic burden of cellulase expression. Glycerol production was decreased significantly, up to threefold, in amino acid-supplemented cultures, apparently due to redox balancing. Disproportionately higher levels of glycerol production by Y294[CEL5] indicated a potential correlation between the redox balance of anabolism and the physiological stress of cellulase production. With the reliance on cellulase expression in yeast for the development of consolidated bioprocesses for bioethanol production, this work demonstrates the need for development of yeasts that are physiologically robust in response to burdens imposed by heterologous enzyme production.     

Engineering of vesicle trafficking improves heterologous protein secretion in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is a widely used platform for the production of heterologous proteins of medical or industrial interest. However, heterologous protein productivity is often restricted due to the limitations of the host strain. In the protein secretory pathway, the protein trafficking between different organelles is catalyzed by the soluble NSF (N-ethylmaleimide-sensitive factor) receptor (SNARE) complex and regulated by the Sec1/Munc18 (SM) proteins. In this study, we report that over-expression of the SM protein encoding genes SEC1 and SLY1, improves the protein secretion in S. cerevisiae. Engineering Sec1p, the SM protein that is involved in vesicle trafficking from Golgi to cell membrane, improves the secretion of heterologous proteins human insulin precursor and α-amylase, and also the secretion of an endogenous protein invertase. Enhancing Sly1p, the SM protein regulating the vesicle fusion from endoplasmic reticulum (ER) to Golgi, increases α-amylase production only. Our study demonstrates that strengthening the protein trafficking in ER-to-Golgi and Golgi-to-plasma membrane process is a novel secretory engineering strategy for improving heterologous protein production in S. cerevisiae.     

A kinetic model for quantitative evaluation of the effect of hydrogen and osmolarity on hydrogen production by Caldicellulosiruptor saccharolyticus

Background

The main technological impediment to widespread utilization of lignocellulose for the production of fuels and chemicals is the lack of low-cost technologies to overcome its recalcitrance. Organisms that hydrolyze lignocellulose and produce a valuable product such as ethanol at a high rate and titer could significantly reduce the costs of biomass conversion technologies, and will allow separate conversion steps to be combined in a consolidated bioprocess (CBP). Development of Saccharomyces cerevisiae for CBP requires the high level secretion of cellulases, particularly cellobiohydrolases.

Results

We expressed various cellobiohydrolases to identify enzymes that were efficiently secreted by S. cerevisiae. For enhanced cellulose hydrolysis, we engineered bimodular derivatives of a well secreted enzyme that naturally lacks the carbohydrate-binding module, and constructed strains expressing combinations of cbh1 and cbh2 genes. Though there was significant variability in the enzyme levels produced, up to approximately 0.3 g/L CBH1 and approximately 1 g/L CBH2 could be produced in high cell density fermentations. Furthermore, we could show activation of the unfolded protein response as a result of cellobiohydrolase production. Finally, we report fermentation of microcrystalline cellulose (Avicel?) to ethanol by CBH-producing S. cerevisiae strains with the addition of beta-glucosidase.

Conclusions

Gene or protein specific features and compatibility with the host are important for efficient cellobiohydrolase secretion in yeast. The present work demonstrated that production of both CBH1 and CBH2 could be improved to levels where the barrier to CBH sufficiency in the hydrolysis of cellulose was overcome.     

Secretion of human serum albumin by Kluyveromyces lactis overexpressing KlPDI1 and KlERO1

The control of protein conformation during translocation through the endoplasmic reticulum is often a bottleneck for heterologous protein production. The core pathway of the oxidative folding machinery includes two conserved proteins: Pdi1p and Ero1p. We increased the dosage of the genes encoding these proteins in the yeast Kluyveromyces lactis and evaluated the secretion of heterologous proteins. KlERO1, an orthologue of Saccharomyces cerevisiae ERO1, was cloned by functional complementation of the ts phenotype of an Scero1 mutant. The expression of KlERO1 was induced by treatment of the cells with dithiothreitol and by overexpression of human serum albumin (HSA), a disulfide bond-rich protein. Duplication of either PDI1 or ERO1 led to a similar increase in HSA yield. Duplication of both genes accelerated the secretion of HSA and improved cell growth rate and yield. Increasing the dosage of KlERO1 did not affect the production of human interleukin 1beta, a protein that has no disulfide bridges. The results confirm that the ERO1 genes of S. cerevisiae and K. lactis are functionally similar even though portions of their coding sequence are quite different and the phenotypes of mutants overexpressing the genes differ. The marked effects of KlERO1 copy number on the expression of heterologous proteins with a high number of disulfide bridges suggests that control of KlERO1 and KlPDI1 is important for the production of high levels of heterologous proteins of this type.     

Effects of inactivation and constitutive expression of the unfolded- protein response pathway on protein production in the yeast Saccharomyces cerevisiae

One strategy to obtain better yields of secreted proteins has been overexpression of single endoplasmic reticulum-resident foldases or chaperones. We report here that manipulation of the unfolded-protein response (UPR) pathway regulator, HAC1, affects production of both native and foreign proteins in the yeast Saccharomyces cerevisiae. The effects of HAC1 deletion and overexpression on the production of a native protein, invertase, and two foreign proteins, Bacillus amyloliquefaciens alpha-amylase and Trichoderma reesei endoglucanase EGI, were studied. Disruption of HAC1 caused decreases in the secretion of both alpha-amylase (70 to 75% reduction) and EGI (40 to 50% reduction) compared to the secretion by the parental strain. Constitutive overexpression of HAC1 caused a 70% increase in alpha-amylase secretion but had no effect on EGI secretion. The invertase levels were twofold higher in the strain overexpressing HAC1. Also, the effect of the active form of T. reesei hac1 was tested in S. cerevisiae. hac1 expression caused a 2.4-fold increase in the secretion of alpha-amylase in S. cerevisiae and also slight increases in invertase and total protein production. Overexpression of both S. cerevisiae HAC1 and T. reesei hac1 caused an increase in the expression of the known UPR target gene KAR2 at early time points during cultivation.     

Development of a screening method for the indentification of a novelSaccharomyces cerevisiae mutant over-expressingTrichoderma reesei cellobiohydrolase II

In a previous study we showed that the fusion of the cellulose-binding domain (CBD2) fromTrichoderma reesei cellobiohydrolase II to a β-glucosidase (BGL1) enzyme fromSaccharomycopsis fibuligera significantly hindered its expression and secretion inSaccharomyces cerevisiae. This suggests that the possible low secretion of heterologous cellulolytic enzymes inS. cerevisiae could be attributed to the presence of a cellulose-binding domain (CBD) in these enzymes. The aim of this study was to increase the extracellular production of the chimeric CBD2-BGL1 enzyme (designated CBGL1) inS. cerevisiae. To achieve this, CBGL1 was used as a reporter enzyme for screening mutagenisedS. cerevisiae strains with increased ability to secrete CBD-associated enzymes such as cellulolytic enzymes. A mutant strain ofS. cerevisie, WM91-CBGL1, which exhibited up to 200 U L^?1 of total activity, was isolated. Such activity was approximately threefold more than that of the parental host strain. Seventy-five per cent of the activity was detected in the extracellular medium. The mutant strain transformed with theT. resei CBH2 gene produced up to threefold more cellobiohydrolase enzyme than the parental strain, but with 50% of the total activity retained intracellularly. The cellobiohydrolase enzymes from the parent and mutant strains were partially purified and the characteristic properties analysed.     

Enzyme production by recombinant Trichoderma reesei strains.

The production of both homologous and heterologous proteins with the cellulolytic filamentous fungus Trichoderma reesei is described. Biotechnically important improvements in the production of cellulolytic enzymes have been obtained by genetic engineering methodology to construct strains secreting novel mixtures of cellulases. These improvements have been achieved by gene inactivation and promoter changes. The strong and highly inducible promoter of the gene encoding the major cellulase, cellobiohydrolase I (CBHI) has also been used for the production of eukaryotic heterologous proteins in Trichoderma. The expression and secretion of active calf chymosin is described in detail.