Clostridium saccharobutylicum利用玉米秸秆水解液发酵生产燃料丁醇

以Clostridium saccharobutylicum DSM 13864为丁醇生产菌株,采用正交优化法确定了以玉米秸秆水解液为底物的最优培养基配方:CaCO32.0 g/L,(NH4)2SO41.0 g/L,K2HPO40.5 g/L,玉米浆干粉15 g/L,MnSO4.H2O 0.01 g/L。采用该最优培养基配方,在3 L发酵罐中发酵培养40 h后,总溶剂为16.1 g/L,其中丁醇10.59 g/L,发酵强度为0.40 g/(L·h),生产率为0.33 g/g。通过对发酵过程进行变温调控证实低温有利于溶剂积累,总溶剂由17.01 g/L提高至19.98 g/L。在稀释率为0.1 h-1的变温连续发酵过程中,从80 h开始进入稳定产溶剂状态并持续至269 h,该阶段平均总溶剂为12.28 g/L(其中丁醇8.50 g/L),发酵强度为1.23 g/(L·h),是变温分批发酵(D方式)的4.92倍。

利用Clostridium saccharobutylicum DSM 13864连续发酵生产丁醇

为使用廉价糖质原料进行连续发酵生产丁醇提供理论依据和实验指导,以Clostridium saccharobutylicumDSM 13864为发酵菌种,考察了稀释率和温度等因素对以葡萄糖为原料的四级连续发酵生产丁醇的影响。结果表明:高稀释率有利于酸的积累和菌体的生长,低稀释率有利于溶剂的生产。当稀释率为0.05 h 1,4个发酵罐温度控制在37℃时,总溶剂产量为11.57 g/L,其中丁醇7.29 g/L,生产率为0.145 g/(L.h)。在0.05 h 1稀释率的条件下进行变温连续发酵证实低温有利于溶剂的积累,当一级和二级罐温度控制在37℃,三级和四级罐温度控制在33℃时总溶剂产量最高为13.69 g/L,其中丁醇为8.36 g/L,生产率为0.171 g/(L.h)。

Clostridium saccharobutylicum DSM 13864细胞表面理化特性及固定化细胞产丁醇的性能

糖丁基梭菌Clostridium saccharobutylicum DSM 13864能利用多种糖类为底物发酵产丁醇。本文研究了该菌体细胞表面的理化特性,并以砖块作为细胞固定化材料进行丁醇发酵。采用细菌吸附有机溶剂（MATS）法证明糖丁基梭菌细胞表面有强烈的亲水性,并且等电点在p H值为3左右,这些特性有利于菌体与表面亲水多孔的砖块吸附。在60g/L葡萄糖发酵培养基中,以5~8目砖块作为固定化材料,流速为1.1L/min,发酵48h后,丁醇的浓度、得率和生产率分别达到11.02g/L、0.18g/g和0.23g/（L？h）,相比悬浮细胞发酵分别提高了10.53%、5.88%和9.52%。结果表明：砖块作为一种固定化材料可有效提高糖丁基梭菌的发酵产丁醇水平。

Coproduction of xylose and biobutanol from corn stover via recycling of sulfuric acid pretreatment solution

Sulfuric acid was used in the pretreatment of corn stover to obtain xylose as a value-added by-product,and the pretreated corn stover(Pre-CS)was hydrolyzed to produce glucose for butanol fermentation.The aim of this work is to achieve high xylose accumulation and reduced wastewater by recycling the pretreatment solution.The pretreatment conditions were optimized as follows:180°C,15 min,1:7 solid-liquid ratio(w/w),0.6%H_(2)SO_(4)(w/w,first batch)/0.9%H_(2)SO_(4)(w/w,second and third batches),in which pretreatment solution was recycled for three times.Under above conditions,pretreatment solution containing 56.3 g/L xylose and 4.5 g/L glucose was obtained.Pre-CS residue was further hydrolyzed by cellulase to achieve 35.7-39.9 g/L glucose.The condensed corn stover hydrolysate was subjected to simultaneous detoxification and sterilization using 1%(w/w)activated carbon and then applied in butanol fermentation.The highest butanol titer of 9.5 g/L was obtained in 72 h.The results provide a practical approach for coproducing xylose and biobutanol from corn stover.

糖丁基梭菌产丁醇途径在大肠杆菌中的构建及发酵

【目的】通过克隆来源于糖丁基梭菌(Clostridium saccharobutylicum DSM13864)丁醇合成途径的关键酶基因(thl A,bcs-operon和adh E),构建产丁醇大肠杆菌。【方法】以Clostridium saccharobutylicum DSM13864的基因组为模板,分别扩增丁醇途径关键酶基因thl A,bcs-operon(crt-bcd1-etf B2-fix B2-hbd)和adh E,构建了两个重组质粒p ETDuet-bcs和pRSFDuet-thl A-adh E,并成功转入E.coli JM109(DE3)实现异源表达,使大肠杆菌具备产丁醇能力。在半厌氧条件下进行重组菌的发酵,并研究不同培养基对产丁醇的影响。【结果】该重组菌在半厌氧条件下经摇瓶发酵丁醇产量达到25.4 mg/L,通过优化培养基后,在TB发酵培养基中丁醇产量可达到34.1 mg/L。【结论】通过构建重组共表达质粒,将糖丁基梭菌来源的丁醇途径关键酶基因在大肠杆菌中表达,成功构建产丁醇大肠杆菌。该研究提供了一株易于操作的丁醇发酵重组大肠杆菌,避免了传统梭菌发酵丁醇生产中苛刻的厌氧条件、易产孢子等限制问题。