利用棒杆菌由N－乙酰氨基肉桂酸制备L－苯丙氨酸

从土壤中分离到一株棒杆菌（ＣｏｒｙｎｅｂａｃｔｅｔｉｕｍＳｐ．），可利用Ｎ－乙酰氨基肉桂酸作底物，通过酰基转移和氨基转移两步酶促反应，生成Ｌ－苯丙氨酸。利用０．２ｍｏｌ／Ｌ的乙酰氨基肉桂酸可生成０．０６ｍｏｌ／Ｌ的Ｌ－苯丙氨酸，摩尔转化率可达３０％。     

泸型大曲中根霉固态发酵产糖化酶条件研究

对泸型大曲中根霉菌株固态发酵产糖化酶的条件进行了研究。以糖化酶活力为评价指标,设计单因素实验,研究培养基水分含量、培养时间、培养温度对根霉产糖化酶的影响,在此基础上,利用Box—BenhnkenDesign的方法,对根霉菌株固态发酵产糖化酶的条件进行优化,结果显示泸型大曲中根霉菌株固态发酵产糖化酶的优化条件为培养温度29℃,培养基水分含量53％,培养时间164h,糖化酶的酶活力为2194．44U／g。     

Co-Production of Fungal Biomass Derived Constituents and Ethanol from Citrus Wastes Free Sugars without Auxiliary Nutrients in Airlift Bioreactor

The potential of two zygomycetes fungi, Mucor indicus and Rhizopus oryzae, in assimilating citrus waste free sugars (CWFS) and producing fungal chitosan, oil, and protein as well as ethanol was investigated. Extraction of free sugars from citrus waste can reduce its environmental impact by decreasing the possibility of wild microorganisms growth and formation of bad odors, a typical problem facing the citrus industries. A total sugar concentration of 25.1 g/L was obtained by water extraction of citrus waste at room temperature, used for fungal cultivation in shake flasks and airlift bioreactor with no additional nutrients. In shake flasks cultivations, the fungi were only able to assimilate glucose, while fructose remained almost intact. In contrast, the cultivation of M. indicus and R. oryzae in the four-liter airlift bioreactor resulted in the consumption of almost all sugars and production of 250 and 280 g fungal biomass per kg of consumed sugar, respectively. These biomasses correspondingly contained 40% and 51% protein and 9.8% and 4.4% oil. Furthermore, the fungal cell walls, obtained after removing the alkali soluble fraction of the fungi, contained 0.61 and 0.69 g chitin and chitosan per g of cell wall for M. indicus and R. oryzae, respectively. Moreover, the maximum ethanol yield of 36% and 18% was obtained from M. indicus and R. oryzae, respectively. Furthermore, that M. indicus grew as clump mycelia in the airlift bioreactor, while R. oryzae formed spherical suspended pellets, is a promising feature towards industrialization of the process.     

Characteristics of L-lactic Acid Production byRhizopus oryzae mutant RL6041

A high-yield mutant strain Rhizopus oryzae RL6041 induced by ions implantation was used in the present study. L (+)-lactic acid was generated by RL6041 grown on liquefied corn starch as a substrate. With optimal conditions (Liquefied corn starch 150g/L, (NH₄)₂SO₄ 2.0g/L, MgSO₄·7H₂O 1.0g/L, ZnSO₄·7H₂O 2g/L, KH₂PO₄ 0.2g/L, CaCO₃ 8%, medium size 20/250Ml, seed age 6h, fermentation temperature 38° C), the yield of L (+)-lactic acid in shake-flask reached 133～136g/L after 36h, indicating that the conversion rate was as high as 88%～91%, and the productivity was 3.75g/L·h. There was almost a 70% increase in lactic acid production compared with the original strain RE3303.     

少根根霉发酵糖质原料积累

少根根霉Ｒ＿３０菌株摇瓶发酵过程中的酶活分析及间接实验表明：Ｌ－苹果酸积累的关键酶是苹果酸脱氢酶（Ｅ．Ｃ．１．１．１．３７），Ｒ＿３０菌株的Ｌ－苹果酸积累主要是通过草酰乙酸还原及丙酮酸羧化，ＴＣＡ循环及乙醛酸循环主要用于维持菌体的正常代谢．     

光学纯度L(+)-乳酸高产菌株的选育

从60份不同来源的土壤样品中筛选得到米根霉(Rhizopus oryzae)为出发菌株,通过紫外线和60Coγ射线诱变处理,运用推理育种技术,选育到一株有较高的乳酸脱氢酶活性和耐高渗的L( )-乳酸高产突变株Rhi3-2.该菌株产L( )-乳酸光学纯度高,最高产量为88.45g/L,较出发菌株提高91.24%,糖利用率提高17.87%,耗糖酸产率提高35.15%.菌株经8次传代培养,L( )-乳酸产量下降10.7%,是一株性状较稳定可深入研究开发的优良菌株.     

氮离子注入选育高效发酵木糖生产L(+)-乳酸的米根霉

为了获得能够高效发酵木糖生产L( )-乳酸的菌株,采用氮离子注入诱变方法,对出发菌株米根霉RLC41-6进行改良,获得高产L( )-乳酸菌株RQ4012,发酵周期为72h,产酸能力达74.37g/L,产酸速率达1.03g/(L.h),比RLC41-6提高了1.6倍.经过多次传代实验证明该菌株具有较好的遗传稳定性.     

Production of active lipase by Rhizopus oryzae from sugarcane bagasse: solid state fermentation in a tray bioreactor

This study deals with production of lipase in solid state fermentation by Rhizopus oryzae from sugarcane bagasse. A tray bioreactor was designed for the extracellular enzyme production. Daily, lipase production was evaluated at several incubation temperatures. Furthermore, the influence of temperature and humidity of the cabinet, depth of solid bed, particle size, initial moisture content and supplementary substrate (olive oil) as carbon source was investigated. The obtained results showed that bioreactor temperature of 45 °C, humidity of 80%, solid bed depth of 0.5 cm, particle size in the range of 0.335–1 mm, substrate initial moisture content of 80% for the top tray and 70% for the middle tray and supplementary substrate of 8% (v/w) olive oil led to maximum lipase production. Under optimum fermentation conditions after 72‐h incubation, maximum lipase activities for the top, middle and bottom trays were 215.16, 199.36 and 52.64 U gds^?1, respectively.     

Lipolytic Enzyme Production by Immobilized Rhizopus oryzae

In this paper, a suitable technique as well as an adequate material for the immobilization of the fungus Rhizopus oryzae were investigated. This organism has been shown to have potential in the field of food aroma due to the production of extracellular lipolytic enzymes. However, an efficient production system at bioreactor scale for its application to the flavor compounds production is still needed. Among the supports studied, alginate beads were the best carrier materials, leading to the highest lipolytic activities of up to 400 U/L after 3 days of cultivation. Repeated batch cultures were carried out to improve cell concentration and lipolytic activity. The gel beads produced lipolytic enzyme under optimized conditions for consecutive batch fermentations without marked activity loss and deformation attained a maximum level of 715 U/L after three batches. The production of lipolytic enzyme by immobilized Rhizopus oryzae in a 2‐litre airlift bioreactor with the optimized conditions was evaluated. Lipolytic activities of 487 U/L were attained, operating in successive batches without operational problems and the bioparticles (the fungus grows in alginate beads) maintained their shape throughout fermentation.