羊肚菌液态发酵的研究

通过摇瓶正交试验研究了圆锥羊肚菌液体发酵的条件,选出最佳培养基配方、接种量、培养温度、pH、通气量,培养时间等参数。在此基础上,应用VIRTIS公司生产的2L－自控发酵罐进行了分批发酵,摸索到了羊肚菌液态深层发酵的基本规律,然后分别以淀粉和玉米粉为碳源进行了补料分批发酵,获得其干细胞产量为25．4g／L和27．4g／L,生长速率为0．45g／（L·h）和0．51g／（L·h）,以碳源为基准的产量得率系数（yx／s）为0.72（g／g）和0.75（g／g）等数据。实验结果表明,羊肚菌的液态深层发酵已达到了真菌菌丝液态发酵的正常水平。     

羊肚菌液态发酵的研究

通过摇瓶正交试验研究了圆锥羊肚菌液体发酵的条件,选出最佳培养基配方,接种量,培养温度、ｐＨ,通气量,培养时间等参数,在此基础上,应用ＶＩＴＲＩＳ公司生产的２Ｌ－自控发酵罐进行了分批发酵,摸索到了羊肚菌液态深层发酵的基本规律,然后分别以淀粉和玉米粉的碳源进行了补料分批发酵。     

根瘤菌4012a菌株产细胞分裂素发酵条件的研究

用酶标免疫检测法研究了根瘤菌4012a菌株细胞分裂素发酵的适宜培养基和培养条件。结果表明,其最佳培养基为（g／L）：葡萄糖10.0,（NH4）2SO41.0,K2HPO4·3H2O0．6,MgSO4·7H2O0.1,CaCl2·2H2O0.4,FeCI3·6H2O0．04,Na2MoO4·2H2O0．1mg／L,泛酸钙100μg／L,腺漂吟200mg／L。该菌株在150r／min的旋转摇床上27℃振荡培养96h,发酵液中细胞分裂素产量可达908μg／L,生物活性（萝卜子叶扩大法）为1mg／L激动素当量。     

高浓度糖发酵制备乙醇

以树干毕赤酵母为发酵菌株,混合糖（木糖、葡萄糖）为发酵底物,通过培养基和培养条件的改变来确定树干毕赤酵母高糖浓度发酵时所需的条件。研究结果表明：在24h发酵周期内初始木糖质量浓度为63．0g／L较适宜;在36h发酵周期内初始木糖质量浓度为72．0g/L较适宜。24h发酵周期内,在36．0g／L木糖中添加的葡萄糖质量浓度以54．0g/L为最佳,发酵结束乙醇质量浓度达32．9g／L;36h发酵周期内,添加的葡萄糖质量浓度以72．0g／L为最佳,发酵结束乙醇质量浓度为36．9g／L。以（NH4）2SO4为N源时较适合戊糖发酵制备乙醇,（NH2）2SO4的最佳质量浓度为1．1g／L。发酵前8h摇床转速为90r／min,后16h为150r／min,乙醇质量浓度较高,可达17．5g/L。     

手性拆分环氧氯丙烷菌株的筛选、鉴定及产酶条件研究

从土壤中筛选到5株环氧化物水解酶生产菌,并通过ITS序列鉴定了其中的C375菌,结果为黑曲霉（Aspergillus nigerZJB-09103）。考察了培养基不同碳源、氮源、金属离子和pH等对产酶的影响,得到了较佳的培养基条件：淀粉16g／L,豆饼粉3g／L,蛋白胨3g／L,KH2PO4 0．4g／L,K2HPO4 0．8g／L,MgSO4 0．2g／L,ZnSO4 0．03g／L,pH6．5。采用优化后的培养基条件,酶活力达到156．1U／L,比优化前初始发酵培养条件下的酶活提高了252％,当环氧化物水解酶催化时间为10h时,（s）-环氧氯丙烷的对映体过量值（e．e．）可达99．0％。产率为18．6％。     

响应面法优化产酰胺酶发酵培养基

采用响应面分析方法,对阿萨希丝孢酵母（Trichosporon asahii）ZZB-1产酰胺酶的发酵培养基进行了优化。运用单N子试验筛选出麦芽糖和酵母浸膏为最适碳源、氮源,金属离子Ca^2＋、Mn^2＋可提高发酵酰胺酶产量;通过最陡爬坡实验逼近以上4个因子的最大响应区域后,采用Box—Behnken响应面分析法,确定产酰胺酶最佳发酵培养基为麦芽糖18．84g／L、酵母浸膏9．55g／L、NaC15g／L、KH2PO41g／L、MgSO4·7H2O0．2g／L、FeS040．001g／L、CaC0370．84μmol／L、MnS0465．39肚mo[／L（1％丙烯酸诱导）,NH4·H2O调节pH至7．0。培养基优化后酰胺酶产量由初始2554U／L提高到4156U／L,为原始发酵培养基配方酶活产量的1．63倍。     

氮源种类及溶氧水平对锁掷酵母产类胡萝卜素组分的影响

在锁掷酵母（Sporidioboluspararoseus）发酵产类胡萝卜紊的过程中,发酵产物中类胡萝卜紊种类繁多,而且性质相似,加大了不同色素分离纯化的难度。为定向积累不同种类的类胡萝卜素,以本实验室保藏锁挪酵母JD-2为出发菌,研究了氮源种类和浓度及溶氧对锁掷酵母产类胡萝卜素的影响,并在7L发酵罐中进行了补料分批发酵试验。发现培养基中同时添加有机氮源和无机氮源且溶氧控制较低（5％）时有利于β-胡萝卜素的大量积累,最佳有机氮源和无机氮源分别为玉米浆（20g／L）、硫酸铵（5g／L）。补料分批发酵时β-胡萝卜素产量达到31．28mg／L,红酵母烯12．38mg／L。培养基中只添加有机氮源且相对溶氧控制相对较高（30％）时有利于红酵母烯的大量积累,最佳有机氮源为酵母膏（20g／L）。补料分批发酵时红酵母烯产量达到38．96mg／L,8．胡萝卜素12．36mg／L。     

酪酸梭状芽孢杆菌低成本培养基的优化

本文重点在于提高酪酸梭状芽孢杆菌活菌数量,降低发酵培养基成本。通过对发酵培养基中不同碳源、氮源、生长因子等进行单因素研究,得到最佳培养基组成：可溶性淀粉10/L,豆粕（中性蛋白酶水解3h）20g／L,玉米浆3g／L。用此培养基在37℃培养24h,采用高层半固体琼脂试管法对酪酸梭状芽孢杆菌进行活菌计数,活菌数可达8．2×10^8cfu／mL.培养基中添加K2HPO45g／L、MgSO4·7H2O0．2g／L、MnSO3·H2O0．2g/L培养32h时,酪酸梭状芽孢杆菌芽孢转化率可达95％。     

一株具有藻毒素清除功能的干酪乳杆菌细胞高密度发酵条件优化

为提高一株具有藻毒素清除能力的干酪乳杆菌Lactobacillus casei BBEi0—212单位体积的活菌数,针对其营养需求,研究了不同碳源、氮源、缓冲盐、微量元素及生长因子对该菌株生长情况及发酵特性的影响。通过响应面法对碳源、氮源、生长因子等进行优化,获得最佳培养基配方为：α-乳糖43．8g/L,酵母膏79．5g/L,无水乙酸钠13．12g／L,冰醋酸9．17mL／L,MnSO4·H20190mg／L,吐温-805．15mL/L。经37℃培养18h,菌体干重达到4．97g/L,比在普通MRS培养基中（1．32g／L）提高近4倍。基于乳酸菌发酵过程中的产酸特性,通过外源添加5g／L谷氨酸,促使菌体浓度进一步提高15％,并提前1．2h进入生长稳定期。上述研究结果为食品行业重要生产菌株干酪乳杆菌的高密度培养技术提供了可借鉴的研究思路。     

营养物质对桑黄菌丝生物量及胞外多糖产量的影响

研究了不同碳源、氮源和无机盐对桑黄深层培养菌丝生物量和胞外多糖产量的影响,结果表明：在培养温度为26℃、摇床转速为160r／min、发酵时间为10d的条件下,以桑黄菌丝生物量为指标,最适碳源、氮源和无机盐分别是果糖或葡萄糖、酵母粉或酵母膏、KH2P04或MgSO4·7H2O;菌丝生物量分别达到1．51、1．31、1．69、1．52、1．52、1．36g／100mL;以胞外多糖为指标,最适碳源、氮源和无机盐分别是葡萄糖、酵母膏、ZnSO4·7H2O,胞外多糖产量分别达到0．49、0．45、0．22g／100mL。     

丙酮酸发酵过程中光滑球拟酵母过程功能的强化

对不同葡萄糖浓度下光滑球拟酵母分批发酵生产丙酮酸的动力学模型分析发现, 葡萄糖浓度是影响光滑球拟酵母发酵生产丙酮酸过程功能的关键因素。在发酵初始阶段, 低浓度葡萄糖可维持较高的菌体比生长速率; 对数生长中前期, 葡萄糖快速进料使菌体浓度接近最大值, 并实现碳流从菌体生长转向丙酮酸积累; 对数生长后期葡萄糖浓度控制在33.4 g/L以维持高丙酮酸对葡萄糖产率系数 (0.71 g/g)。采用奇异控制的葡萄糖流加方式, 在7 L发酵罐上控制不同发酵阶段葡萄糖浓度处于最佳水平以强化光滑球拟酵母过程功能, 丙酮酸产量 (83.1 g/L)、产率 (0.621 g/g)、生产强度[1.00 g/(L·h)]与分批发酵对比, 分别提高了21.3%、21.6%和29.9%。     

过量表达苹果酸脱氢酶对大肠杆菌NZN111产丁二酸的影响

大肠杆菌NZN111是敲除了乳酸脱氢酶的编码基因 (ldhA) 和丙酮酸-甲酸裂解酶的编码基因 (pflB) 的工程菌,厌氧条件下由于辅酶NAD(H) 的不平衡导致其丧失了代谢葡萄糖的能力。构建了苹果酸脱氢酶的重组菌大肠杆菌NZN111/pTrc99a-mdh,在厌氧摇瓶发酵过程中通过0.3 mmol/L的IPTG诱导后重组菌的苹果酸脱氢酶 (Malate dehydrogenase,MDH) 酶活较出发菌株提高了14.8倍,NADH/NAD+的比例从0.64下降到0.26,同时NAD+和NADH浓度分别     

循环利用重组大肠杆菌细胞转化合成丁二酸

研究了回收丁二酸发酵液中的大肠杆菌进行细胞转化的可行性,以转化率和生产效率为指标,考察了不同菌体浓度、底物浓度、pH调节剂对细胞转化的影响。发酵结果表明大肠杆菌可以在仅含有葡萄糖和pH调节剂的水环境中转化生产丁二酸,并确定了最佳的转化条件为:细胞浓度(OD600)50,底物浓度40g/L,缓冲盐为MgCO3。基于优化好的条件,在7L发酵罐中进行重复批次转化,第1次转化的转化率和生产效率分别达到91%和3.22g/(L·h),第2次转化的生产效率和转化率达到了86%和2.04g/(L·h),第3次转化的转化率和生产效率分别达到了83%和1.82g/(L·h)。     

Production of hydrogen from marine macro-algae biomass using anaerobic sewage sludge microflora

Hydrogen was produced from various marine macro-algae (seaweeds) through anaerobic fermentation using an undefined bacterial consortium. In this study, anaerobic fermentation from various marine macro-algae for Ulva lactuca, Porphyra tenera, Undaria pinnatifida, and Laminaria japonica was studied. From this analysis Laminaria japorica was determined to be the optimum substrate for hydrogen production. When L. japornica was used as the carbon source for enhanced hydrogen production, the optimum fermentation temperature, substrate concentration, initial pH, and pretreatment condition were determined to be 35°C, 5%, 7.5, and BT120 (Ball mill and thermal treatments at 120°C for 30 min), respectively. In addition, hydrogen production was improved when the sludge was heat-treated at 65°C for 20 min. Under these conditions, about 4,164 mL of hydrogen was produced from 50 g/L of dry algae (L. japonica) for 50 h, with a hydrogen concentration around 34.4%. And the maximum hydrogen production rate and yield were found to be 70 mL/L·h and 28 mL/g dry algae, respectively.     

法夫酵母PLX-All发酵纤维素酶水解物合成虾青素

法夫酵母（Phaffia rhodozyma)PLX-All菌株能够发酵纤维素酶水解物进行虾青素的生物合成。纤维素的酶解物主要为纤维二糖和葡萄糖,在另外添加适量其它营养物后可被法夫酵母发酵用于生长及合成虾青素。摇瓶试验结果表明,培养108h,法夫酵母的生物量可达2.3g／L,虾青素的产率达913.4g／g干细胞,虾青素体积产率为2.1mg／L。在2L罐的发酵试验中,法夫酵母的生物量可达3.23g／L（第96h）,虾青素的产率达581.4g／g干细胞,虾青素体积产率达1.88mg／L。     

法夫酵母PLX-All发酵纤维素酶水解物合成虾青素*

法夫酵母（Phaffia rhodozyma)PLX-All菌株能够发酵纤维素酶水解物进行虾青素的生物合成。纤维素的酶解物主要为纤维二糖和葡萄糖,在另外添加适量其它营养物后可被法夫酵母发酵用于生长及合成虾青素。摇瓶试验结果表明,培养108h,法夫酵母的生物量可达2.3g／L,虾青素的产率达913.4g／g干细胞,虾青素体积产率为2.1mg／L。在2L罐的发酵试验中,法夫酵母的生物量可达3.23g／L（第96h）,虾青素的产率达581.4g／g干细胞,虾青素体积产率达1.88mg／L。     

Kinetics of ethanol fermentations in membrane cell recycle fermentors

Ethanol fermentation by yeast was carried out in a cell filtration recycle system with a hollow-fiber membrane filter. Maximum biomass concentrations up to 210 g dry wt/L were obtained, but in normal operation concentrations they were between 100 and 150 g/L. The ethanol productivity using 14% glucose feed was 85 g/L h, with an ethanol concentration of 65 g/L and an ethanol yield of over 90%. The ethanol productivity and yeast growth rate decreased as the cell concentration increased beyond a certain level. The cell mass in the reactor was maintained by a proper manipulation of diluticn rate and bleed ratio depending on the growth rate.     

Studies on Cell Suspension Culture and Fermentation Culture in Arnebia euchroma

This paper reports some characteristics of cell suspension and fermentation culture in Arnebia euchroma (Royle) Johnst. The yield of suspension culture reached 22.0g dry wt/L per month when inoculum quantity was 2.50 g dry wt/L. Time-course study showed that cell growith lagged in 0–3 days and enhanced greatly in 3–12 days, and almost ceased after 12 days of culture, pH value changed during the culture period and peaked on the 12th day after inoculation. When cells were cultured in liquid production medium, the contents of shikonin derivatives increased quickly and reached to the maximum about the 25th day. The cell yield of 9.47 and 9.34 g dry wt/L per month was obtained in fermentation culture. Timecourse of cell growth in fermentation culture was similar to that in suspension culture. The total content of shikonin derivatives in fermentation culture was 14.26% dry weight from 10 L bioreactor. The yield of shikonin derivatives was 1.93 g/L.     

Simultaneous saccharification and fermentation of acid-pretreated rapeseed meal for succinic acid production using Actinobacillus succinogenes

Rapeseed meal was evaluated for succinic acid production by simultaneous saccharification and fermentation using Actinobacillus succinogenes ATCC 55618. Diluted sulfuric acid pretreatment and subsequent hydrolysis with pectinase was used to release sugars from rapeseed meal. The effects of culture pH, pectinase loading and yeast extract concentration on succinic acid production were investigated. When simultaneous saccharification and fermentation of diluted acid pretreated rapeseed meal with a dry matter content of 12.5% (w/v) was performed at pH 6.4 and a pectinase loading of 2% (w/w, on dry matter) without supplementation of yeast extract, a succinic acid concentration of 15.5 g/L was obtained at a yield of 12.4 g/100g dry matter. Fed-batch simultaneous saccharification and fermentation was carried out with supplementation of concentrated pretreated rapeseed meal and pectinase at 18 and 28 h to yield a final dry matter content of 20.5% and pectinase loading of 2%, with the succinic acid concentration enhanced to 23.4 g/L at a yield of 11.5 g/100g dry matter and a productivity of 0.33 g/(Lh). This study suggests that rapeseed meal may be an alternative substrate for the efficient production of succinic acid by A. succinogenes without requiring nitrogen source supplementation.     

魔芋葡甘聚糖酶实验性生产条件初探

在5L发酵罐上用正交试验检测不同温度、pH和接种量对魔芋葡甘聚糖酶发酵生产的影响。试验表明,产酶的最佳条件为温度50℃,pH5.5～6.0,接种量10%,发酵前期搅拌速度100r·min-1,通气量20L·h-1,6h后搅拌速度改为50r·min-1,通气量10L·h-1,在此条件下获得的酶比活力为4.812×106U·g-1,总活力达到7.810×106U·L-1。培养8h后细菌生物量、产物含量迅速提高,24h达到顶峰时期。发酵动力学属于偶联型。