汉逊德巴利酵母发酵葡萄糖生产D-阿拉伯糖醇

从378株耐高渗酵母中,筛选到1株由葡萄糖发酵高产D-阿拉伯糖醇的酵母。通过生理生化和分子生物学的鉴定,证实该菌株为Debaryomyces hansenii,保藏编号CICIM Y 0504。研究该酵母摇瓶发酵的主要影响因素,确定其摇瓶发酵条件为:葡萄糖200 g/L,酵母膏10 g/L,初始pH值3,装液量20 mL/250 mL,温度30℃。在此条件下发酵120 h,D-阿拉伯糖醇浓度达90.37 g/L,转化率45.18%。在15 L发酵罐对该酵母进行扩大培养,结果表明,初始葡萄糖浓度200 g/L的分批发酵产D-阿拉伯糖醇64.07 g/L,转化率33.94%;葡萄糖浓度控制在30～50 g/L的分批补料发酵产D-阿拉伯糖醇125 g/L,转化率37.5%。研究结果对葡萄糖发酵生产D-阿拉伯糖醇工业化的实现具有重要启示。     

细菌血红蛋白基因在产D-阿拉伯糖醇酵母菌中的克隆与表达

构建了含透明颤菌血红蛋白基因vgb和甲醛抗性基因SFA1的重组质粒pVgb EX2 ,转化到产D 阿拉伯糖醇的酵母Saccharomycessp.X 62中。转化子细胞中VHb的含量比对照菌细胞有显著提高 ,表明基因vgb在酵母细胞中得到表达。转化子发酵的D 阿拉伯糖醇产量与转化率均有提高。在重复实验中D 阿拉伯糖醇的产量最多提高了 2 7 3%。在实验条件下 ,似乎D 阿拉伯糖醇的产量与细胞VHb含量有相关性。     

D-阿拉伯糖结晶影响因素分析

D-阿拉伯糖是多种功能性糖合成的中间体,其纯度高低决定了功能性糖转化率的高低,所以得到高纯度的D-阿拉伯糖尤为重要。通过对D-阿拉伯糖结晶温度、搅拌速度、结晶液中离子含量等因素进行试验,确定了采用梯度降温形式、搅拌速度控制在5 r/min,离子含量控制在100 μs/cm以下能够得到纯度达99.8%的D-阿拉伯糖晶体,实验结果为后续功能性糖的高效转化奠定了基础。     

产D-阿拉伯醇菌株的筛选、鉴定及其产D-阿拉伯醇条件的优化

摘要：【目的】产D-阿拉伯醇的耐高渗酵母的筛选、鉴定和产D-阿拉伯醇条件的优化。【方法】通过电镜、Biolog GN、(G+C)含量和26S rDNA D1/D2区序列分析法对所获得的菌株进行了描述。通过红外光谱、核磁共振氢谱和碳谱、质谱以及旋光度实验鉴定纯化产物的结构。通过单因素实验优化产D-阿拉伯醇的发酵条件。【结果】本文筛选得到一株产D-阿拉伯醇的新型菌株,经鉴定属于假丝酵母属并命名为Candida sp. H2。200 mL摇瓶发酵生产D-阿拉伯醇的单因素优化实验表明,最适发酵条件为：葡萄糖250     

表面活性剂对林可霉素发酵生产的影响

在林可霉素发酵过程中,当向培养基中加入表面活性剂十二烷基磺酸钠(SDS)、吐温80(Tween 80)和曲拉通(Triton X-100)时,林可霉素的产量受到较大影响。本研究应用响应面设计法(Response surface design)对表面活性剂的配比进行了优化,得到的优化配比为:十二烷基磺酸钠为31.13 mg/100 mL,吐温80为51.97 mg/100 mL,曲拉通为16.9 mg/100 mL。将该优化配比应用于林可霉素发酵,产量提高了36.67%。     

非离子表面活性剂对生物丁醇发酵的影响

传统的丙酮-丁醇发酵的产物浓度过低(丁醇终浓度约为1.3 wt%),导致后期分离成本过高,从而影响了该过程的经济性,限制了其工业化进程。本文研究了高添加量的小分子非离子表面活性剂对生物丁醇发酵的影响。以吐温80为例,实验表明,当表面活性剂添加量超过其临界胶束浓度后,丁醇发酵的终浓度会随着表面活性剂添加量的增加而增加。当添加量达到5 wt%时,丁醇终浓度可以达到1.6 wt%,远高于该菌种的抑制浓度(0.8 wt%)。为阐明表面活性剂的作用机理,实验考察了吐温80对丁醇的增溶效应以及对发酵菌体表面亲疏水性的影响。结果表明,吐温80对丁醇的增溶效果很小,而对菌体表面的亲疏水性有较明显的影响。     

Gluconobacter oxydans NH-10中短链D-阿拉伯糖醇脱氢酶的研究

以氧化葡萄糖酸杆菌(Gluconobacter oxydans)NH-10基因组DNA为模板,扩增得到D-阿拉伯糖醇脱氢酶基因arDH,将其克隆到大肠杆菌表达载体JM109(DE3)中进行诱导表达。SDS-PAGE电泳分析ArDH的分子量约为30 kDa,是一个短链脱氢酶,既能催化D-阿拉伯糖醇氧化为D-木酮糖,又能催化D-木酮糖还原为D-阿拉伯糖醇。催化氧化反应时,对D-阿拉伯糖醇的K_m为60.67 mmol/L,V_max为0.803 U/mg;它能同时依赖于NAD⁺和NADP⁺,但是更加偏好辅酶NAD⁺;最适pH为12.0。还原反应对D-木酮糖的 K_m为36.39 mmol/L,V_max为1.71 U/mg;最优pH为7.0,最适温度均为30℃。     

生物转化生产D-塔格糖的食品级菌种选育及L-阿拉伯糖异构酶的克隆表达

L-阿拉伯糖异构酶(L-arabinose isomerase,L-AI)是一种可以催化D-半乳糖为D-塔格糖的胞内异构化酶。随着塔格糖在食品工业中越来越广泛的应用,能够将半乳糖转化为塔格糖的食品级微生物以及食品级来源的L-AI受到更大的关注。文中从各种酸奶制品、泡菜及其他一些食品中采集不同的样品,筛选出1株具有L-AI酶活的食品级菌株,经过生理生化鉴定以及16S rDNA序列测定,确定该菌株为戊糖片球菌,命名为Pediococcus pentosaceus PC-5。以该菌基因组为模板,克隆L-AI基因,并在大肠杆菌BL21成功地异源表达。表达产物经粗提取后,在40℃下加入Mn2+,使D-半乳糖转化为D-塔格糖的转化率为33%。     

假丝酵母E-2产生物表面活性剂摇瓶发酵条件的优化

从扬子石化的废水淤泥中筛选到1株能发酵液体石蜡产脂肽类生物表面活性剂的假丝酵母Candida E-2.通过单因子实验和正交试验,得到了最佳发酵培养基组成(g/L):牛肉膏3.0,蔗糖2.0,酵母膏0.25,KH2PO4 12.5,MgSO4 0.3,NaCl 1.5,CaCl,0.05,尿素0.5 5;液体石蜡10％(体积分数).最佳培养条件:初始pH7.0,接种量0.12g/L,装液量为200mL三角瓶30mL,培养时间为5 d.最终产量提高了2.7倍,达1.582g/L.     

Casein Digestion by Debaryomyces hansenii Isolated from Cheese

To understand the possible proteolytic contribution of yeast during cheese ripening, Debaryomyces hansenii 212 was isolated from commercial blue-veined cheese and incubated in a medium containing casein. Growth and casein degradation were recognized at the cheese-ripening temperature. Proteolytic activity was found in the intracellular fraction, and the enzyme, which was attached to the cell wall, primarily acted on β-casein. The cytosol contained more than 90% of the total proteolytic activity which was responsible for the degradation of both α_s- and β-casein. These results suggest that the contribution of yeast to cheese ripening would depend on the susceptibility to cell lysis in addition to its proteolytic activity.     

Oxidative stress sensitivity in Debaryomyces hansenii

Debaryomyces hansenii is an osmotolerant and halotolerant yeast of increasing interest for fundamental and applied research. In this work, we have performed a first study on the effect of oxidative stress on the performance of this yeast. We have used Saccharomyces cerevisiae as a well-known reference yeast. We show that D. hansenii is much more susceptible than S. cerevisiae to cadmium chloride, hydrogen peroxide or 1,4-dithiothreitol. These substances induced the formation of reactive oxygen species (ROS) in both yeasts, the amounts measured being significantly higher in the case of D. hansenii . We also show that NaCl exerted a protective effect against oxidative stress in Debaryomyces , but that this was not the case in Saccharomyces because sodium protected that yeast only when toxicity was induced with cadmium. On the basis of the present results, we raised the hypothesis that the sensitivity to oxidative stress in D. hansenii is related to the high amounts of ROS formed in that yeast and that observations such as low glutathione amounts, low basal superoxide dismutase and peroxidase activities, decrease in ATP levels produced in the presence of ROS inducers and high cadmium accumulation are determinants directly or indirectly involved in the sensitivity process.     

Mechanisms underlying the halotolerant way of Debaryomyces hansenii

The yeast Debaryomyces hansenii is usually found in salty environments such as the sea and salted food. It is capable of accumulating sodium without being intoxicated even when potassium is present at low concentration in the environment. In addition, sodium improves growth and protects D. hansenii in the presence of additional stress factors such as high temperature and extreme pH. An array of advantageous factors, as compared with Saccharomyces cerevisiae, is putatively involved in the increased halotolerance of D. hansenii: glycerol, the main compatible solute, is kept inside the cell by an active glycerol-Na+ symporter; potassium uptake is not inhibited by sodium; sodium protein targets in D. hansenii seem to be more resistant. The whole genome of D. hansenii has been sequenced and is now available at http://cbi.labri.fr/Genolevures/ and, so far, no genes specifically responsible for the halotolerant behaviour of D. hansenii have been found.     

Activation of fermentation by salts in Debaryomyces hansenii

The presence of 1.0 M KCl or NaCl during growth of Debaryomyces hansenii results in increased ethanol production. An additional increase of fermentation was observed when the salts were also present during incubation under nongrowing conditions. Extracts of cells grown in the presence of salt showed increased alcohol dehydrogenase and phosphofructokinase activities, indicating that these enzymes are responsible for the increased fermentation capacity. This is confirmed by measurements of the glycolytic intermediates. The increased fermentation capacity of the cells grown with salts seems to enable them to cope with the additional energy required for uptake and/or efflux of cations.     

Production and characteristics of Debaryomyces hansenii killer toxin

The optimal conditions for the production of the killer toxin of Debaryomyces hansenii CYC 1021 have been studied. The lethal activity of the killer toxin increased with the presence of NaCl in the medium used for testing the killing action. Production of the killer toxin was stimulated in the presence of proteins of complex culture media. Addition of nonionic detergents and other additives, such as dimethylsulfoxide enhanced killer toxin production significantly. Killer toxin secretion pattern followed the growth curve and reached its maximum activity at the early stationary phase. Optimal stability was observed at pH 4.5 and temperatures up to 20 °C. Above pH 4.5 a steep decrease of the stability was noted. The activity was hardly detectable at pH 5.1.     

Influence of temperature and pH on xylitol production from xylose by Debaryomyces hansenii

The production of xylitol from concentrated synthetic xylose solutions (S(o) = 130-135 g/L) by Debaryomyces hansenii was investigated at different pH and temperature values. At optimum starting pH (pH(o) = 5.5), T = 24 degrees C, and relatively low starting biomass levels (0.5-0.6 g(x)/L), 88% of xylose was utilized for xylitol production, the rest being preferentially fermented to ethanol (10%). Under these conditions, nearly 70% of initial carbon was recovered as xylitol, corresponding to final xylitol concentration of 91.9 g(P)/L, product yield on substrate of 0.81 g(P)/g(S), and maximum volumetric and specific productivities of 1.86 g(P)/L x h and 1.43 g(P)/g(x) x h, respectively. At higher and lower pH(o) values, respiration also became important, consuming up to 32% of xylose, while negligible amounts were utilized for cell growth (0.8-1.8%). The same approach extended to the effect of temperature on the metabolism of this yeast at pH(o) = 5.5 and higher biomass levels (1.4-3.0 g(x)/L) revealed that, at temperatures ranging from 32-37 degrees C, xylose was nearly completely consumed to produce xylitol, reaching a maximum volumetric productivity of 4.67 g(P)/L x h at 35 degrees C. Similarly, both respiration and ethanol fermentation became significant either at higher or at lower temperatures. Finally, to elucidate the kinetic mechanisms of both xylitol production and thermal inactivation of the system, the related thermodynamic parameters were estimated from the experimental data with the Arrhenius model: activation enthalpy and entropy were 57.7 kJ/mol and -0.152 kJ/mol x K for xylitol production and 187.3 kJ/mol and 0.054 kJ/mol x K for thermal inactivation, respectively.     

Phosphate limitation stress induces xylitol overproduction by Debaryomyces hansenii

The physiological responses of xylose-grown Debaryomyces hansenii were studied under different nutritive stress conditions using continuous cultivation at a constant dilution rate of 0.055 h⁻¹. Metabolic steady-state data were obtained for xylose, ammonium, potassium, phosphate and oxygen limitation. For xylose and potassium limitation, fully oxidative metabolism occurred leading to the production of biomass and CO₂ as the only metabolic products. However, potassium-limiting cultivation was the most severe nutritional stress of all tested, exhibiting the highest xylose and O₂ specific consumption rates along with the lowest biomass yield, 0.22 g g⁻¹ xylose. It is suggested that carbon was mainly channelled to meet the cellular energy requirements for potassium uptake. For the other limiting nutritional conditions increasing amounts of extracellular xylitol were found for ammonium, phosphate and oxygen limitation. Although xylitol excretion is not significant for ammonium limitation, the same is not true for phosphate limitation where the xylitol productivity reached 0.10 g l⁻¹ h⁻¹, about half of that found under oxygen-limiting conditions, 0.21 g l⁻¹ h⁻¹. This work is the first evidence that xylitol production by D. hansenii might not only be a consequence of a redox imbalance usually attained under semi-aerobic conditions, but additional physiological mechanisms must be involved, especially under phosphate limitation. Cell yields changed drastically as a function of the limiting nutrient, being 0.22, 0.29, and 0.39 g g⁻¹ xylose for potassium, oxygen and phosphate limitation, respectively, and are a good indicator of the severity of nutritive stress.     

Proteomic changes in Debaryomyces hansenii upon exposure to NaCl stress

The proteome of the highly NaCl-tolerant yeast Debaryomyces hansenii was investigated by two-dimensional polyacrylamide gel electrophoresis (2D PAGE), and 47 protein spots were identified by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) followed by mass spectrometry (MS). The influence of NaCl on the D. hansenii proteome was investigated during the first 3 h of NaCl exposure. The rate of protein synthesis was strongly decreased by exposure to 8% and 12% (w/v) NaCl, as the average incorporation rates of l-[(35)S]methionine within the first 30 min after addition of NaCl were only 7% and 4% of the rate in medium without NaCl. In addition, the number of protein spots detected on 2D gels prepared from cells exposed to 8% and 12% (w/v) NaCl exceeded less than 28% of the number of protein spots detected on 2D gels prepared from cells without added NaCl. Several proteins were identified as being either induced or repressed upon NaCl exposure. The induced proteins were enzymes involved in glycerol synthesis/dissimilation and the upper part of glycolysis, whereas the repressed proteins were enzymes involved in the lower part of glycolysis, the route to the Krebs cycle, and the synthesis of amino acids. Furthermore, one heat shock protein (Ssa1p) was induced, whereas others (Ssb2p and Hsp60p) were repressed.     

Differential detection of Debaryomyces hansenii isolated from intermediate-moisture foods by PCR-RFLP of the IGS region of rDNA

The amplification by PCR of the Intergenic Spacer region (IGS) of rDNA followed by Restriction Fragment Length Polymorphism (RFLP) analysis was evaluated as a potential method for the identification of Debaryomyces hansenii among other yeast species that frequently contaminate Intermediate-Moisture Foods (IMFs). For a first rapid differentiation at the species level, the determination of the IGS-PCR fragment size was found to be a useful approach. The digestion of this region with the enzymes HhaI, HapII and MboI resulted in specific patterns that permit the identification of D. hansenii among other yeast species. This method also permitted the discrimination between the D. hansenii varieties (var. hansenii and var. fabryi) as well as the differentiation of D. hansenii from other species of the genus, such as Debaryomyces pseudopolymorphus or Debaryomyces polymorphus var. polymorphus. The IGS-PCR RFLP method was assayed for the differential detection of D. hansenii in contaminated or spoiled IMF products and compared with traditional identification procedures, resulting in a 100% detection rate for D. hansenii.