自絮凝工业酒精酵母营养缺陷型的筛选和鉴定

运用紫外诱变方法成功获得了自絮凝酵母的营养缺陷型突变体,并且优化了诱变方法,证明了通过紫外诱变也可获得自絮凝酵母的营养缺陷型突变体。实验证明,较低的致死率更容易获得突变体,利用制霉菌素的富集可明显减少非缺陷型背景。本实验获得了组氨酸和尿嘧啶营养缺陷型各一株,其中组氨酸缺陷型茵株失去絮凝特性,而尿嘧啶缺陷型保持了良好的絮凝特性。继代实验表明,二株突变体均可以稳定遗传。并利用交配型PCR方法证明了絮凝酵母及其两株突变体与其酿酒酵母亲本类似,均为交配型杂合体。     

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。     

Observed quasi-steady kinetics of yeast cell growth and ethanol formation under very high gravity fermentation condition

Using a generalSaccharomyces cerevisiae as a model strain, continuous ethanol fermentation was carried out in a stirred tank bioreactor with a working volume of 1,500 mL. Three different gravity media containing glucose of 120, 200 and 280 g/L, respectively, supplemented with 5 g/L yeast extract and 3 g/L peptone, were fed into the fermentor at different dilution rates. Although complete steady states developed for low gravity medium containing 120 g/L glucose, quasi-steady states and oscillations of the fermented parameters, including residual glucose, ethanol and biomass were observed when high gravity medium containing 200 g/L glucose and very high gravity medium containing 280 g/L glucose were fed at the designated dilution rate of 0.027 h⁻¹. The observed quasi-steady states that incorporated these steady states, quasi-steady states and oscillations were proposed as these oscillations were of relatively short periods of time and their averages fluctuated up and down almost symmetrically. The continuous kinetic models that combined both the substrate and product inhibitions were developed and correlated for these observed quasi-steady states.     

自絮凝酵母高浓度重复批次乙醇发酵

利用发酵性能优良的自絮凝酵母Saccharomyces cerevisiaeflo,研究开发了重复批次高浓度乙醇发酵系统,以节省下游加工过程的能耗。在终点乙醇浓度达到120g/L左右的条件下,发酵系统的乙醇生产强度达到8.2g/(L·h)。然而实验中发现,随着发酵批次的增多,自絮凝酵母沉降性能逐渐下降,从发酵液中沉降分离所需时间相应延长,导致发酵液中高浓度乙醇对酵母的毒害作用加剧,影响其发酵活性和发酵系统运行的稳定性,发酵装置运行11个批次后无法继续运行。实验结果表明,絮凝能力下降导致的酵母絮凝颗粒尺度减小是其沉降性能下降的主要原因。进一步研究发现,酵母的絮凝能力通过再培养可以恢复。在此基础上对发酵系统操作进行改进,每批发酵结束后可控采出一定比例菌体,调节系统的酵母细胞密度和乙醇生产强度以刺激酵母增殖,保持其絮凝能力。在达到相同发酵终点乙醇浓度条件下,虽然发酵系统的乙醇生产强度降低到4.0g/(L·h),但运行10d后絮凝颗粒酵母尺度趋于稳定,继续运行14d,未发现絮凝颗粒酵母尺度继续下降的现象,系统可以稳定运行。     

自絮凝颗粒酵母乙醇连续发酵耦合废液全循环工艺的研究

在以CO2为驱动力的单级悬浮床生物反应器中,进行了自絮凝颗粒酵母乙醇连续发酵耦合废液全循环实验研究。以双酶法制备的玉米粉糖化液为底物,系统连续运行了28 d,每隔5 d将收集到的发酵液集中精馏处理,得到的废糟液直接用于玉米粉调浆制糖。实验数据表明,在稀释率为0.05 h-1条件下,发酵液中乙醇、残还原糖、残总糖质量浓度基本稳定,其平均值为82.97,30.02和40.87 g.L-1。对废液循环工艺过程中,发酵液中的8种高沸点有机酸进行了定量分析,发现发酵液中仅丙酮酸有明显积累,并最终在0.1~0.3 mol.L-1范围内波动。实验结果表明:系统中存在的高沸点副产物不对乙醇发酵产生明显抑制作用,乙醇连续发酵能够在废液全循环条件下良好运行。     

木薯粉与甘蔗糖蜜混合发酵高浓度酒精

对木薯粉与甘蔗糖蜜混合原料发酵高浓度酒精的条件进行了优化,先应用P-B(Plackett-Burman)试验筛选影响混合原料高浓度酒精发酵的重要影响因素,结果表明,初始总糖浓度、糖蜜添加时间、初始pH值是影响混合原料酒精发酵的重要因素。采用最陡爬坡实验找到响应面试验的中心点,再利用Box-Behnken设计确定重要参数的最佳水平。各因素的最佳水平是:总糖浓度为29.14%,添加时间为16.5 h,初始pH值为4.7。1 L发酵罐验证试验酒精浓度可达16.07%(V/V)。优化后酒精浓度提高了20%。     

Optimization of an ethanol production medium in very high gravity fermentation

Concentrations of Mg²⁺, glycine, yeast extract, biotin, acetaldehyde and peptone were optimized by a uniform design process for ethanol production by Saccharomyces cerevisiae. Using non-linear step-wise regression analysis, a predictive mathematical model was established. Concentrations of Mg²⁺ and peptone were identified as the critical factors: 50 mM Mg²⁺ and 1.5% (w/v) peptone in the medium increased the final ethanol titre from 14.2% (v/v) to 17% (v/v) in 48 h.     

初始条件对高浓度乙醇连续发酵过程的影响及振荡行为提高发酵效率的机理分析

前期实验在稀释速率为0.027h-1的高浓度乙醇连续发酵过程中,发现了一种长周期、宽振幅的参数振荡现象。本实验进一步考察了不同稀释速率下的连续发酵过程,发现在稀释速率为0.04h-1条件下,也能出现类似的振荡现象;在稀释速率为0.027h-1或0.04h-1的条件下,改变系统的初始状态可以得到振荡和稳态两种不同的发酵过程。比较振荡和稳态过程的实验数据后,发现在稀释速率为0.04h-1的条件下,与稳态过程相比,振荡过程的平均残糖浓度降低了14.8%,平均乙醇浓度提高了12.6%,平均设备生产强度提高了12.3%。进一步分析表明:与稳态过程相比,振荡过程动力学行为不仅存在滞后,而且在相同残糖和乙醇浓度条件下,所对应的平均比生长速率提高了53.8%。     

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.     

A novel strategy to construct yeast Saccharomyces cerevisiae strains for very high gravity fermentation

Very high gravity (VHG) fermentation is aimed to considerably increase both the fermentation rate and the ethanol concentration, thereby reducing capital costs and the risk of bacterial contamination. This process results in critical issues, such as adverse stress factors (ie., osmotic pressure and ethanol inhibition) and high concentrations of metabolic byproducts which are difficult to overcome by a single breeding method. In the present paper, a novel strategy that combines metabolic engineering and genome shuffling to circumvent these limitations and improve the bioethanol production performance of Saccharomyces cerevisiae strains under VHG conditions was developed. First, in strain Z5, which performed better than other widely used industrial strains, the gene GPD2 encoding glycerol 3-phosphate dehydrogenase was deleted, resulting in a mutant (Z5ΔGPD2) with a lower glycerol yield and poor ethanol productivity. Second, strain Z5ΔGPD2 was subjected to three rounds of genome shuffling to improve its VHG fermentation performance, and the best performing strain SZ3-1 was obtained. Results showed that strain SZ3-1 not only produced less glycerol, but also increased the ethanol yield by up to 8% compared with the parent strain Z5. Further analysis suggested that the improved ethanol yield in strain SZ3-1 was mainly contributed by the enhanced ethanol tolerance of the strain. The differences in ethanol tolerance between strains Z5 and SZ3-1 were closely associated with the cell membrane fatty acid compositions and intracellular trehalose concentrations. Finally, genome rearrangements in the optimized strain were confirmed by karyotype analysis. Hence, a combination of genome shuffling and metabolic engineering is an efficient approach for the rapid improvement of yeast strains for desirable industrial phenotypes.     

Very high gravity ethanol fermentation by flocculating yeast under redox potential-controlled conditions

ABSTRACT: BACKGROUND: Very high gravity (VHG) fermentation using medium in excess of 250 g/L sugars for more than 15 % (v) ethanol can save energy consumption, not only for ethanol distillation, but also for distillage treatment; however, stuck fermentation with prolonged fermentation time and more sugars unfermented is the biggest challenge. Controlling redox potential (ORP) during VHG fermentation benefits biomass accumulation and improvement of yeast cell viability that is affected by osmotic pressure and ethanol inhibition, enhancing ethanol productivity and yield, the most important techno-economic aspect of fuel ethanol production. RESULTS: Batch fermentation was performed under different ORP conditions using the flocculating yeast and media containing glucose of 201 [PLUS-MINUS SIGN] 3.1, 252 [PLUS-MINUS SIGN] 2.9 and 298 [PLUS-MINUS SIGN] 3.8 g/L. Compared with ethanol fermentation by non-flocculating yeast, different ORP profiles were observed with the flocculating yeast due to the morphological change associated with the flocculation of yeast cells. When ORP was controlled at [MINUS SIGN]100 mV, ethanol fermentation with the high gravity (HG) media containing glucose of 201 [PLUS-MINUS SIGN] 3.1 and 252 [PLUS-MINUS SIGN] 2.9 g/L was completed at 32 and 56 h, respectively, producing 93.0 [PLUS-MINUS SIGN] 1.3 and 120.0 [PLUS-MINUS SIGN] 1.8 g/L ethanol, correspondingly. In contrast, there were 24.0 [PLUS-MINUS SIGN] 0.4 and 17.0 [PLUS-MINUS SIGN] 0.3 g/L glucose remained unfermented without ORP control. As high as 131.0 [PLUS-MINUS SIGN] 1.8 g/L ethanol was produced at 72 h when ORP was controlled at [MINUS SIGN]150 mV for the VHG fermentation with medium containing 298 [PLUS-MINUS SIGN] 3.8 g/L glucose, since yeast cell viability was improved more significantly. CONCLUSIONS: No lag phase was observed during ethanol fermentation with the flocculating yeast, and the implementation of ORP control improved ethanol productivity and yield. When ORP was controlled at [MINUS SIGN]150 mV, more reducing power was available for yeast cells to survive, which in turn improved their viability and VHG ethanol fermentation performance. On the other hand, controlling ORP at [MINUS SIGN]100 mV stimulated yeast growth and enhanced ethanol production under the HG conditions. Moreover, the ORP profile detected during ethanol fermentation with the flocculating yeast was less fluctuated, indicating that yeast flocculation could attenuate the ORP fluctuation observed during ethanol fermentation with non-flocculating yeast.     

Improvement of very high gravity ethanol fermentation by media supplementation using Saccharomyces cerevisiae

The final ethanol concentration achieved was increased by 17% (to 103 g ethanol/l) when excess assimilable nitrogen was added to the batch very high gravity (VHG) ethanolic fermentations by Saccharomyces cerevisiae. The supplementation of the media with 12 g yeast extract l–1, 0.3 g cell walls l–1, 3 g glycine l–1 and 20 g soya flour l–1 led to halving reduction of the fermentation time to 28 h. The ethanol productivity was enhanced by more than 50% (to achieved value 3.3 g l–1 h–1).     

Characterization of very high gravity ethanol fermentation of corn mash. Effect of glucoamylase dosage, pre-saccharification and yeast strain

Ethanol was produced from very high gravity mashes of dry milled corn (35% w/w total dry matter) under simultaneous saccharification and fermentation conditions. The effects of glucoamylase dosage, pre-saccharification and Saccharomyces cerevisiae strain on the growth characteristics such as the ethanol yield and volumetric and specific productivity were determined. It was shown that higher glucoamylase doses and/or pre-saccharification accelerated the simultaneous saccharification and fermentation process and increased the final ethanol concentration from 106 to 126 g/kg although the maximal specific growth rate was decreased. Ethanol production was not only growth related, as more than half of the total saccharides were consumed and more than half of the ethanol was produced during the stationary phase. Furthermore, a high stress tolerance of the applied yeast strain was found to be crucial for the outcome of the fermentation process, both with regard to residual saccharides and final ethanol concentration. The increased formation of cell mass when a well-suited strain was applied increased the final ethanol concentration, since a more complete fermentation was achieved.     

Very high gravity wort fermentation by immobilised yeast

Using calcium alginate-entrapped yeast, 24% (w/w) wort was successfully fermented within 8 days. This is half the time needed for fermentation by free yeast. The highest ethanol concentration obtained was 10.5% (v/v). When the original wort gravity was increased, the specific rate of ethanol production remained constant 0.16 g gh^–1 and the viability did not fall bellow 95% of living cells. Protection of cell against osmotic stress by gel matrix was also confirmed by trehalose measurement. The maximum intracellular trehalose content in calcium alginate-entrapped yeast was 3 times lower compared to free yeast at 30% (w/w) wort fermentation.     

Impact of zinc supplementation on the improvement of ethanol tolerance and yield of self-flocculating yeast in continuous ethanol fermentation

The effects of zinc supplementation were investigated in the continuous ethanol fermentation using self-flocculating yeast. Zinc sulfate was added at the concentrations of 0.01, 0.05 and 0.1 g l(-1), respectively. Reduced average floc sizes were observed in all the zinc-supplemented cultures. Both the ethanol tolerance and thermal tolerance were significantly improved by zinc supplements, which correlated well with the increased ergosterol and trehalose contents in the yeast flocs. The highest ethanol concentration by 0.05 g l(-1) zinc sulfate supplementation attained 114.5 g l(-1), in contrast to 104.1 g l(-1) in the control culture. Glycerol production was decreased by zinc supplementations, with the lowest level 3.21 g l(-1), about 58% of the control. Zinc content in yeast cells was about 1.4 microMol g(-1) dry cell weight, about sixfold higher than that of control in all the zinc-supplemented cultures, and close correlation of zinc content in yeast cells with the cell viability against ethanol and heat shock treatment was observed. These studies suggest that exogenous zinc addition led to a reprogramming of cellular metabolic network, resulting in enhanced ethanol tolerance and ethanol production.     

木薯粉与甘蔗汁混合发酵生产高浓度乙醇

对木薯粉和甘蔗汁混合原料进行高温高浓度乙醇发酵的条件进行了优化,在单因素实验的基础上,先应用Plackett-Burman试验设计筛选出影响发酵的重要参数,再利用正交试验设计确定重要因素的最佳水平,即:木薯粉与甘蔗汁的比例为1∶5(W/V),发酵初始pH为4.0～4.5,尿素添加量为0.25%(W/W),硫酸镁添加量为0.04%(W/W)。最后在发酵过程中采用梯度温度控制,可显著提高发酵效率。在技术集成的基础上,进行了2L发酵罐放大实验,经过48h发酵,发酵成熟醪乙醇浓度可达17.84%(V/V),发酵效率达91.82%。     

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。     

Modeling of yeast metabolism and process dynamics in batch fermentation

Much is known about yeast metabolism and the kinetics of industrial batch fermentation processes. In this study, however, we provide the first tool to evaluate the dynamic interaction that exists between them. A stoichiometric model, using wine fermentation as a case study, was constructed to simulate batch cultures of Saccharomyces cerevisiae. Five differential equations describe the evolution of the main metabolites and biomass in the fermentation tank, while a set of underdetermined linear algebraic equations models the pseudo-steady-state microbial metabolism. Specific links between process variables and the reaction rates of metabolic pathways represent microorganism adaptation to environmental changes in the culture. Adaptation requirements to changes in the environment, optimal growth, and homeostasis were set as the physiological objectives. A linear programming routine was used to define optimal metabolic mass flux distribution at each instant throughout the process. The kinetics of the process arise from the dynamic interaction between the environment and metabolic flux distribution. The model assessed the effect of nitrogen starvation and ethanol toxicity in wine fermentation and it was able to simulate fermentation profiles qualitatively, while experimental fermentation yields were reproduced successfully as well.     

A fermentation process for producing both ethanol and lysine-enriched yeast.

In 18 batch-fermentation experiments, baker's yeast was grown in an enriched mineral medium, containing 10% by weight glucose, at various pH and temperature levels. The pH and temperature are just two representative engineering variables which can be easily varied at negligible cost. The commercial yeast inoculum, 20% by weight or about .16% viable cells, was selected to represent industrial (nonsterile) conditions. Free L-lysine, ethanol, and cell growth were followed in time for each batch run held at a fixed pH and temperature. The maximum free lysine level reached at either 10 1/2 or 24 hr occurred at a pH of 5 and 32 degrees C. At 24 hr, the peak free lysine level, 120 mg/liter, is three times as great as the uncontrolled pH counterpart. In terms of total L-lysine (free plus protein-bound) the peak represents a 25% improvement over the uncontrolled case, based on an average 3.5% lysine level per cell weight. The greatest measured cell level, .9% by weight in the fermentation broth, or a 5 1/2-fold increase over th inoculum, was reached during the 36 degrees C and pH 3 run, while the largest measured ethanol value (3%, or 30% conversion by weight from glucose) was achieved during the 28 degrees C and pH 6 experiment. The optimal lysine run product, however, no less than 15% of the maximum cell and 30% of the maximum ethanol levels.