β-葡聚糖酶和木聚糖酶高产菌株的选育及在小麦加工中的应用

以Aspergillus nigerJ5为出发菌株,经Co60γ-射线诱变,筛选到一株β-葡聚糖酶和木聚糖酶活力都较出发菌株高的突变株A-25,其产β-葡聚糖酶和木聚糖酶的合适发酵条件为:大麦粉4%、玉米浆2.5%、NaNO30.4%、Na2HPO40.1%、MgSO4.7H2O0.03%、FeSO4.7H2O0.01%、CaCO30.5%、吐温-800.25%,初始pH6.7,300mL三角瓶的装液量为50mL,在此条件下培养84h,β-葡聚糖酶活力达到1203.9I U/mL,较出发菌株提高35.9%,木聚糖酶活力达到395.2I U/mL,较出发菌株提高27.8%。突变株粗酶液降解工业面粉非淀粉多糖的能力明显高于出发菌株。     

斜卧青霉纤维素酶和木聚糖酶高产菌株的选育

以纤维素酶高产菌株斜卧青霉A50为出发菌株,通过紫外诱变原生质体获得1株木聚糖酶活力提高80%而纤维素酶活力没有改变的6号菌。蛋白质电泳和酶谱检测结果显示,纤维素酶谱基本无差别,而木聚糖酶谱显示6号菌比A50多了一条带。6号菌优化后的产酶培养基组成为:麸皮7%、葡萄糖0.1%,该条件下,纤维素酶活为19.7IU/mL,木聚糖酶活力为215.4IU/mL。     

木聚糖酶生产菌株的筛选及产酶条件的优化

以甘蔗渣半纤维素为碳源,从垃圾场土壤中分离到6株分解半纤维素的菌株。通过固态发酵的木聚糖酶活力比较筛选到1株木聚糖酶活力较高的菌株。该菌株18S rDNA序列与曲霉（Aspergillus sp.）的同源性达97%,根据对菌株形态学分析和18S rDNA序列分析的结果,将该菌株鉴定为曲霉HQ3。HQ3的最佳产酶条件为：甘蔗渣:麸皮为7:3（W/W）,固液比为1:4（W/W）,尿素0.4 %,pH7.0,温度30℃,发酵产酶时间4 d。在最佳产酶条件下,其木聚糖酶活最高可达3421U/g干曲。     

链霉菌产木聚糖酶条件和酶学性质以及重离子诱变对产酶的影响研究

以一株由青藏高原牦牛粪中分离出的链霉菌为出发菌株,对其培养特性、产酶条件和酶学性质进行初步研究.通过重离子诱变,筛选出遗传稳定的高产菌株.结果表明,该菌以玉米芯和麸皮(1∶1)为碳源能高效地诱导木聚糖酶的胞外分泌,其最适培养基和培养条件氮源为酵母膏、初始pH7、培养温度为25℃,在此条件下,第4天酶活力达到峰值3480.25 U/mL.说明该酶能够利用农业废弃物高效生产木聚糖酶.该菌株所产木聚糖酶的最适反应温度为15℃、pH4,属低温酸性木聚糖酶.经重离子诱变后,筛选出一株高产菌株SZ10-7,其酶活力可达5 338.42 U/mL.     

黑曲霉X-1产木聚糖酶液体发酵工艺研究

目的:提高黑曲霉X-1菌株液体发酵木聚糖酶的产量.方法:采用单因素和正交试验对黑曲霉X-1菌株产木聚糖酶液体发酵培养基和培养条件进行了优化.结果:通过正交试验找出最大影响因素为玉米芯和葡萄糖的供应,优化后的最佳培养基和培养条件为:玉米芯粉3%,葡萄糖0.5%,蛋白胨1%,KH2PO4 0.5%,MgSO4·7HO 0.1%,Tween-80 0.‰,pH 6.5,30℃、200r/min摇瓶培养120h.结论:黑曲霉X-1菌株在优化后的培养基和培养条件下,木聚糖酶活力高达1 630.78U,比优化前木聚糖酶活力(724.63U)提高了125.05%.     

耐碱性木聚糖酶产酶菌株的选育

目的:筛选出产碱性木聚糖酶酶活力高的菌株。方法:从碱性环境中采集样品,以自制木聚糖为惟一利碳源,采用刚果红透明圈法于摇瓶发酵法相结合筛选出18株产木聚糖酶酶活较高的菌株,其中1株酶活最高可达335.14 IU/ml。结果:通过培养特性及形态特征初步鉴定为芽孢杆菌。对部分酶学性质研究的结果表明:其作用最适温度60℃,最适pH8.0,在pH9.0条件下仍具有80%酶活力。结论:属于耐碱性木聚糖酶,具有很好的工业应用前景。     

褐藻胶降解菌株S10鉴定及产酶条件优化

探讨了褐藻胶降解菌株S10的生长条件及其对产褐藻胶降解酶活力的影响。以分离自海参肠道的褐藻胶降解菌株S10为研究对象，采用形态学观察结合16S rDNA序列分析，对菌株S10进行菌种鉴定并对其生理生化特性进行测定。以降解酶活力为指标，利用单因素、Plackett-Burman(PB)和响应面法对培养基成分和培养条件进行优化；最后对优化前后的菌株生长量、产酶活力和粗酶液稳定性进行分析。结果表明，菌株S10属于溶藻孤菌(Vibrio algindyticus);当pH 7、接种量2%(体积分数)、装液量150 mL、温度26℃、转速150 r/min、NaCl 3%(质量分数，下同)、海藻酸钠含量1.12%、硫酸铵含量0.44%、培养时间35.95 h条件下，褐藻胶降解酶活力最大(188.18 U/min)。优化后产酶活力提高30%;4℃低温更有利于该酶保存。综上，优化后的菌株S10产褐藻胶降解酶活力较高，能更好地用于降解褐藻胶，可为提高褐藻胶的利用率和进一步发掘褐藻胶寡糖的利用价值提供参考。     

木聚糖酶高产菌株的鉴定及产酶条件的优化

目的:通过了解木聚糖酶高产菌株A79的遗传背景.并优化其产木聚糖酶的液体发酵条件,为下一步工业化生产和木聚糖酶制剂的研制奠定基础.方法:通过形态观察和18S rDNA基因的分子系统进化分析,对菌株A79进行鉴定;通过单因素和均匀设计试验,优化其产胞外木聚糖酶的液体发酵条件.结果:通过对18S rDNA基因的分子系统进化分析,菌株A79被鉴定为黑曲霉(Asperillus niger A79).其最佳产酶培养基为:玉米芯5.0%,麸皮0.5%.纤维物质1.O%,玉米浆1.1%.(NH4)2SO40.8%,蛋白胨0.8%,CaCO3 0.5%,KH2PO4 0.23%,MgSO4,·7H2O 0.08%,微量元素(MaIldels)0.08%,pH自然.最佳发酵条件为:接种量5%(2.0×107),28℃、250r/min振荡培养96h.结论:经优化培养,酶活力由前期的50 000u/ml提高到90000u/ml,增加了近50%.     

一株Bacillus sublitisJH-1发酵产木聚糖酶培养基的响应面优化

利用刚果红透明圈法从秸秆堆肥中筛选出一株产木聚糖酶菌株Bacillus sublitis JH-1,以单因素试验为基础,采用响应面试验设计对Bacillus sublitis JH-1液态发酵产木聚糖酶的培养基进行了优化,得到产木聚糖酶发酵最适条件为:培养温度33℃,p H值6.0,麦芽糖浓度为2.6%,酵母粉浓度为1.2%,KH2PO4浓度为1.2%,发酵产酶量比优化前提高了1.8倍。     

离子注入选育高产木聚糖酶黑曲霉及其发酵条件研究

以黑曲霉A3为出发菌,利用离子注入技术选育出一株遗传性状稳定的木聚糖酶高产突变株AN497,其产酶水平较出发菌从野生型A3菌株的405.6IU/ml提高到586.2IU/ml,即酶产量增加了44.5%;对高产菌进行发酵条件优化,发现以玉米芯粉为主要碳源、用蔗糖代替葡萄糖作为附加碳源,对木聚糖酶的发酵具有明显的促进作用;采用复合的无机氮源 (NH4)2SO4和NaNO3,(1: 2)浓度以10g/L为宜;菌株对发酵通氧量具有较高的要求,摇瓶转速在230r/min时的产酶水平较200r/min要高;通过发酵条件的优化,高产菌株的产酶活力最高可达671.1IU/mL,比出发菌株的产酶量提高了65.5%。     

黑曲霉B0201利用五倍子固体发酵产单宁酶的条件研究

通过比较常规灭菌发酵和生料发酵, 研究黑曲霉B0201利用五倍子固体发酵产单宁酶的条件。结果表明, 在生料发酵过程中, 采用20%五倍子并且以(NH4)2SO4为氮源制备单宁酶的最佳条件为: 液固比=1.6:1、温度30°C、初始pH 6.0。在该条件下通过96 h的培养, 单宁酶的活力可达51.2 U/gds, 是常规灭菌发酵的3.6倍。以上结果显示, 生料发酵生产单宁酶是一种高效可行的方法。     

Optimization of solid substrate fermentation of wheat straw

Optimal conditions for solid substrate fermentation of wheat straw with Chaetomium cellulolyticum in laboratory-scale stationary layer fermenters were developed. The best pretreatment for wheat straw was ammonia freeze explosion, followed by steam treatment, alkali treatment, and simple autoclaving. The optimal fermentation conditions were 80% (w/w) moisture content; incubation temperature of 37 degrees C; 2% (w/w) unwashed mycelial inoculum; aeration at 0.12 L/h/g; substrate thickness of 1 to 2 cm; and duration of three days. Technical parameters for this optimized fermentation were: degree of substance utilization, 27.2%; protein yield/substrate, 0.09 g; biomass yield/bioconverted substrate, 0.40 g; degree of bioconversion of total available sugars in the substrate, 60.5%; specific efficiency of bioconversion, 70.8%; and overall efficiency of biomass production from substrate, 42.7%. Mixed culturing of Candida utilis further increased biomass production by 20%. The best mode of fermentation was a semicontinuous fed-batch fermentation where one-half of the fermented material was removed at three-day intervals and replaced by fresh substrate. In this mode, protein production was 20% higher than in batch mode, protein productivity was maintained over 12 days, and sporulation was prevented.     

Improved ethanol production of a newly isolated thermotolerant Saccharomyces cerevisiae strain after high-energy-pulse-electron beam

Aims: To isolate thermotolerant Saccharomyces cerevisiae with high‐energy‐pulse‐electron (HEPE) beam, to optimize the mutation strain fermentation conditions for ethanol production and to conduct a preliminary investigation into the thermotolerant mechanisms. Methods and Results: After HEPE beam radiation, the thermotolerant S. cerevisiae strain Y43 was obtained at 45°C. Moreover, the fermentation conditions of mutant Y43 were optimized by L3³ orthogonal experiment. The optimal glucose content and initial pH for fermentation were 20% g l^?1 and 4·5, respectively; peptone content was the most neglected important factor. Under this condition, ethanol production of Y43 was 83·1 g l^?1 after fermentation for 48 h at 43°C, and ethanol yield was 0·42 g g^?1, which was about 81·5% of the theoretical yield. The results also showed that the trehalose content and the expression of the genes MSN2, SSA3 and TPS1 in Y43 were higher than those in the original strain (YE0) under the same stress conditions. Conclusions: A genetically stable mutant strain with high ethanol yield under heat stress was obtained using HEPE. This mutant may be a suitable candidate for the industrial‐scale ethanol production. Significance and Impact of the Study: High‐energy‐pulse‐electron radiation is a new efficient technology in breeding micro‐organisms. The mutant obtained in this work has the advantages in industrial ethanol production under thermostress.     

固液态发酵条件对桑叶发酵提取物中降糖活性物质的影响

目的:探讨不同发酵条件对桑叶总黄酮、总多酚含量及体外降糖活性的影响。方法:本研究主要利用比色法考察固态、液态两种发酵条件对桑叶发酵物中总黄酮、总多酚含量的影响,同时建立α-葡萄糖苷酶和α-淀粉酶为体外降糖活性筛选模型,以期筛选最佳发酵条件。结果:液体发酵7 d桑叶70%乙醇提取物对α-葡萄糖苷酶抑制率最高(92.79%);未发酵水提取物对α-淀粉酶抑制率最高(63.68%),其次为液体发酵7 d桑叶70%乙醇提取物(54.81%)。且在生药浓度为10 mg·m L-1时,都高于阳性对照阿卡波糖。结论:利用冠突散囊菌发酵,可以改变桑叶提取物的体外降糖活性,为开发糖尿病药物提供可行思路。     

桑黄液体发酵工艺的研究

通过对桑黄液体发酵培养基、培养条件优化实验研究,以获得具有与桑黄子实体相似功效成分的桑黄菌丝体液体发酵工艺。以菌丝体收率为主要考察指标,采用单因子及L9(34)正交实验的方法,对桑黄液体发酵培养基及培养条件进行优化,确定桑黄液体发酵工艺条件。桑黄液体发酵最佳培养基及培养条件:玉米粉2%,葡萄糖3%,酵母膏0.5%,蛋白胨0.5%,KH2PO40.3%,Mg SO4·7H2O 0.15%,VB120μg/100 m L,p H5.5,接种量8%,培养温度28℃,摇床转数180 r/min,培养周期82 h。优化条件下所获得桑黄菌丝体粉为土黄色,菌丝体平均得率为1.67%,菌丝体黄酮含量(0.84%)与桑黄子实体(0.88%)相当,菌丝体多糖含量(5.15%)是子实体(1.71%)的3倍。可见,该桑黄液体发酵工艺具有较大的推广应用价值。     

Novel Characteristics of Bifidobacterium bifidum in Solid State Fermentation System

Summary The characteristics of Bifidobacterium bifidum grown in solid state fermentation (SSF) system (water content of media 54.5 and 68.8%) was compared with the submerged fermentation (SmF) system (water content of medium: 89.8%). Besides lactic acid (lactate) and acetic acid (acetate), the bacterium was able to secrete propionic acid (propionate) and butyric acid (butyrate) under SSF conditions. However, it only produced lactate and acetate under SmF conditions. The ratio of lactate to acetate was 1.26–1.62:1 in SSF but it was 1:2 in SmF. A higher content of C16:0 and C18:1 as well as a lower content of C18:0 cell membrane fatty acids were observed in SSF than in SmF. There was a lower growth rate, a lower viable count and a longer logarithmic growth phase for B. bifidum cultivated in SSF than in SmF.     

瑞拉菌素产生菌GAO-1-GR-2发酵工艺条件优化研究

对瑞拉菌GAO-1-GR-2的发酵条件进行了单因素研究,通过正交试验设计对该菌株的培养基进行了筛选。并对其发酵条件进行了研究,结果表明：有机氮源以酵母粉和黄豆饼粉为宜;碳源以葡萄糖和饴糖最好,但考虑到发酵成苓,应选用葡萄糖2％。发酵培养基应呈中性,以采用自然pH为宜,pH超过8,或小于7,则会抑制发酵产物活性;通气量为1：0．5最好,能降低20％耗氧量;摇床转速140r／min,培养温度30℃,发酵周期72h。抗生素发酵原粉效价能达到4000μg／mL。     

Overexpression of the OLE1 gene enhances ethanol fermentation by Saccharomyces cerevisiae

 The fermentation characteristics of Saccharomyces cerevisiae strains which overexpress a constitutive OLE1 gene were studied to clarify the relationship between the fatty acid composition of this yeast and its ethanol productivity. The growth yield and ethanol productivity of these strains in the medium containing 15% dextrose at 10 °C were greater than those of the control strains under both aerobic and anaerobic conditions but this difference was not observed under other culture conditions. During repeated-batch fermentation, moreover, the growth yield and ethanol productivity of the wild-type S. cerevisiae increased gradually and then were similar to those of the OLE1-overexpressing transformant in the last batch fermentation. However, the unsaturated fatty acid content (77.6%) of the wild-type cells was lower than that (86.2%) of the OLE1-recombinant cells. These results suggested that other phenomena caused by the overexpression of the OLE1 gene, rather than high unsaturated fatty acid content, are essential to ethanol fermentation by this yeast. Received: 11 June 1999 / Received last revision: 12 November 1999 / Accepted: 28 November 1999     

Optimization of H2SO4-catalyzed hydrothermal pretreatment of rapeseed straw for bioconversion to ethanol: Focusing on pretreatment at high solids content

A central composite design of response surface method was used to optimize H₂SO₄-catalyzed hydrothermal pretreatment of rapeseed straw, in respect to acid concentration (0.5–2%), treatment time (5–20 min) and solid content (10–20%) at 180 °C. Enzymatic hydrolysis and fermentation were also measured to evaluate the optimal pretreatment conditions for maximizing ethanol production. The results showed that acid concentration and treatment time were more significant than solid content for optimization of xylose release and cellulose recovery. Pretreatment with 1% sulfuric acid and 20% solid content for 10 min at 180 °C was found to be the most optimal condition for pretreatment of rapeseed straw for ethanol production. After pretreatment at the optimal condition and enzymatic hydrolysis, 75.12% total xylan and 63.17% total glucan were converted to xylose and glucose, respectively. Finally, 66.79% of theoretical ethanol yielded after fermentation.     

解淀粉芽孢杆菌3-2发酵羽毛产氨基酸

【目的】建立废弃羽毛液体发酵工艺,优化发酵条件,提高羽毛降解率及氨基酸产量,研发新型、高效复合氨基酸肥料。【方法】利用解淀粉芽孢杆菌3-2发酵羽毛,探究温度、发酵时间、羽毛含量、单一碳源、复合碳氮源、金属离子等对废弃羽毛降解效果以及发酵液中氨基酸种类和含量的影响。【结果】废弃羽毛降解率与氨基酸总产量呈负相关。随着发酵时间延长,羽毛降解率增加,当发酵温度为37°C、羽毛添加量为1%、以乳糖为外加碳源、添加Mg2+时,羽毛降解率最高,达到81.92%。随着羽毛添加量增加,氨基酸总含量也增加(在20%范围以内),当发酵温度为37°C、降解时间为108 h、羽毛添加量为10%、乳糖添加量为0.5%、不添加复合碳氮源、不添加金属离子时,氨基酸的种类最全(富含17种氨基酸),总含量最高,达到20.861 g/kg。【结论】利用解淀粉芽孢杆菌3-2发酵废弃羽毛生产氨基酸复合肥料是一种可靠、环保、经济的方法,获得的氨基酸肥料营养齐全。研究结果为新型复合氨基酸肥料的研发提供技术支撑。