Metabolite profiling for analysis of yeast stress response during very high gravity ethanol fermentations

A laboratory strain and an industrial strain of Saccharomyces cerevisiae were grown at high substrate concentration, so-called very high gravity (VHG) fermentation. Simultaneous saccharification and fermentation (SSF) was applied in a batch process using 280 g/L maltodextrin as carbon source. It was shown that known ethanol and osmotic stress responses such as decreased growth rate, lower viability, higher energy consumption, and intracellular trehalose accumulation occur in VHG SSF for both strains when compared with standard laboratory medium (20 g/L glucose). The laboratory strain was the most affected. GC-MS metabolite profiling was applied for assessing the yeast stress response influence on cellular metabolism. It was found that metabolite profiles originating from different strains and/or fermentation conditions were unique and could be distinguished with the help of multivariate data analysis. Several differences in the metabolic responses to stressing conditions were revealed, particularly the increased energy consumption of stressed cells was also reflected in increased intracellular concentrations of pyruvate and related metabolites.     

转酮醇酶及其工业应用

转酮醇酶是磷酸戊糖途径的关键酶,催化二碳单元在酮糖（供体）和醛糖（受体）间的转移。本文综述了该酶的工业生产及应用领域,如乙醇生产,芳香族氨基酸和手性物质的生物合成等。     

Expression of aldehyde dehydrogenase 6 reduces inhibitory effect of furan derivatives on cell growth and ethanol production in Saccharomyces cerevisiae

Yeast dehydrogenases and reductases were overexpressed in Saccharomyces cerevisiae D452-2 to detoxify 2-furaldehyde (furfural) and 5-hydroxymethyl furaldehyde (HMF), two potent toxic chemicals present in acid-hydrolyzed cellulosic biomass, and hence improve cell growth and ethanol production. Among those enzymes, aldehyde dehydrogenase 6 (ALD6) played the dual roles of direct oxidation of furan derivatives and supply of NADPH cofactor to their reduction reactions. Batch fermentation of S. cerevisiae D452-2/pH-ALD6 in the presence of 2 g/L furfural and 0.5 g/L HMF resulted in 20-30% increases in specific growth rate, ethanol concentration and ethanol productivity, compared with those of the wild type strain. It was proposed that overexpression of ALD6 could recover the yeast cell metabolism and hence increase ethanol production from lignocellulosic biomass containing furan-derived inhibitors.     

温度对超高浓度酒精生料发酵体系的影响

通过对超高底物浓度生料发酵中温度的影响研究发现,采用温度梯度的方法可大幅提高酵母的生产效率。以高粱为例,采用35%绝对干物浓度,在新型生料水解酶的配合下,通过合适的逐级降温培养方式,使用普通酒精干酵母,在90h内发酵醪液酒精浓度可达20%(V/V)以上。     

乙醇-沼气双发酵耦联工艺中硫酸根的调控探讨

为了实现木薯燃料乙醇发酵过程的无废(废水)制造目的,提出了乙醇-沼气双发酵耦联工艺。在该工艺中,液化时向发酵液中引入的硫酸根离子是整个系统的限制性因素。硫酸根在厌氧消化过程还原会造成沼液碱度的升高,并且高浓度硫酸盐还原产物硫化物对产甲烷菌和酵母具有毒害作用,因此需要对其进行调控。本文分别采用了氢氧化钙沉淀法和部分蒸馏废液回用法对硫酸根进行调控,都显著降低了系统中硫酸根的浓度。但是,沉淀法会产生设备、管道等结垢堵塞等问题,工业化推广受限。回用法调控效果显著,在不影响酒精发酵的情况可进一步提高回用比例,将硫酸根浓度控制在更低水平。     

The response of the yeast Saccharomyces cerevisiae to sudden vs. gradual changes in environmental stress monitored by expression of the stress response protein Hsp12p

The response of the yeast Saccharomyces cerevisiae to sudden vs. gradual changes in different environmental stress conditions during both respiratory growth and aerobic fermentative growth in the presence of excess glucose was investigated by monitoring the level and rate of expression of the stress response protein Hsp12p using the fluorescent fusion construct Hsp12p-Gfp2p. The initial expression level and the rate of Hsp12p synthesis was significantly greater under glucose-limited conditions in the chemostat ( D <0.14 h⁻¹) compared with when excess glucose was present in the auxostat. Decreasing the dilution rate and the glucose concentration further in the A-stat resulted in increased Hsp12p expression, which was more marked when a rapid rather than a gradual change was affected. Common stress factors such as NaCl, ethanol and elevated temperature caused stress responses in both D-stat and auxo-accelerostat culture. The magnitude of the stress response depended on the stress factor, cultivation conditions as well as the rate of change of the stress factor. The rate of Hsp12p synthesis increased due to all applied stresses, with the observed increase between 2 and 20 times lower when the stress was applied gradually rather than rapidly. The results suggested that the Hsp12p expression rate is a good indicator of applied stress in S. cerevisiae .     

Ethanol fermentation with Kluyveromyces marxianus from Jerusalem artichoke grown in salina and irrigated with a mixture of seawater and freshwater

Aims: To study fuel ethanol fermentation with Kluyveromyces marxianus ATCC8554 from Jerusalem artichoke (Helianthus tuberosus) grown in salina and irrigated with a mixture of seawater and freshwater. Methods and Results: The growth and ethanol fermentation of K. marxianus ATCC8554 were studied using inulin as substrate. The activity of inulinase, which attributes to the hydrolysis of inulin, the main carbohydrate in Jerusalem artichoke, was monitored. The optimum temperatures were 38°C for growth and inulinase production, and 35°C for ethanol fermentation. Aeration was not necessary for ethanol fermentation with the K. marxianus from inulin. Then, the fresh Jerusalem artichoke tubers grown in salina and irrigated with 25% and 50% seawater were further examined for ethanol fermentation with the K. marxianus, and a higher ethanol yield was achieved for the Jerusalem artichoke tuber irrigated with 25% seawater. Furthermore, the dry meal of the Jerusalem artichoke tubers irrigated with 25% seawater was examined for ethanol fermentation at three solid concentrations of 200, 225 and 250 g l^?1, and the highest ethanol yield of 0·467, or 91·5% of the theoretical value of 0·511, was achieved for the slurry with a solid concentration of 200 g l^?1. Conclusions: Halophilic Jerusalem artichoke can be used for fuel ethanol production. Significance and Impact of the Study: Halophilic Jerusalem artichoke, not competing with grain crops for arable land, is a sustainable feedstock for fuel ethanol production.     

超高浓度培养基条件下酵母细胞生长及酒精生成的准稳态动力学研究

在1．5L搅拌式发酵罐中,使用葡萄糖质量浓度分别为120、200、280g／L的培养基进行酿酒酵母Saccharomyces cerevisiae连续发酵生成酒精的动力学研究。研究发现,当培养基中葡萄糖浓度为200和280g／L时,发酵液中残糖浓度、酒精浓度以及菌体生物量从小幅度波动的准稳态发展到大幅度波动的振荡状态。提出了伴有周期性振荡现象准稳态过程的概念,并针对该过程,建立了兼有底物和产物抑制的酵母细胞生长和产物酒精生成动力学模型。     

絮凝颗粒粒度分布对自絮凝酵母SPSC01乙醇耐受能力的影响

利用激光聚焦反射式颗粒测量系统, 通过调节不同的搅拌速率, 得到了分批补料培养条件下粒度分布不同的四个絮凝酵母SPSC01颗粒群体, 进而对絮凝颗粒群体分布对乙醇耐受性进行了系统研究。经过6 h、20%乙醇的冲击, 颗粒粒度为100、200、300和400 mm的自絮凝酵母SPSC01的存活率分别为3.5%、26.7%、48.8%和37.6%。这表明不同粒度分布的絮凝颗粒群体乙醇耐受性具有明显差别, 在一定粒度范围内乙醇耐受性达到最高, 乙醇耐受性最高的酵母群体的乙醇得率系数85.5%, 比乙醇耐性最低的颗粒群体提高了7.2%。粒度为100、200和300 mm的自絮凝酵母颗粒群体总麦角固醇、游离麦角固醇及海藻糖含量与粒度大小成正相关, 但在粒度为400 mm的絮凝颗粒群体中总麦角固醇、游离麦角固醇及海藻糖含量呈下降趋势, 与其乙醇耐性低于300 mm絮凝颗粒的结果相一致。对细胞膜透性的研究表明, 颗粒粒度为300 mm的絮凝酵母颗粒细胞膜通透性(P′)最低, 分别仅为颗粒粒度为100 mm和200 mm颗粒群体的43%和52%, 表明粒度分布不同的絮凝颗粒群体乙醇耐性的差别与细胞膜透性密切相关。     

微胶囊固定化酵母培养的研究

进行了ＮａＣＳＰＤＭＤＡＡＣ微胶囊固定化酒精酵母和产朊假丝酵母的实验研究。考察了这两种酵母的培养规律,发现微胶囊固定化酒精酵母的产酒精情况与游离培养基本一致,在连续发酵１６批后,仍具有良好的性能。同时固定化产谷胱甘肽（ＧＳＨ）的产朊假丝酵母的研究也表明固定化培养ＧＳＨ产量与游离细胞产量相近