Degradation Kinetics of Xylose and Glucose in Hydrolysate Containing Dilute Sulfuric Acid

In preparation of fuel alcohol from biomass as feedstock, hydrolysis with dilute acid as catalyst is one way to produce fermentable saccharide, xylose and glucose. However, the acid is also the catalyst in degradation of xylose and glucose and the yield of sacchride is dependent on the kinetic behaviors of saccharide. The degradation kinetics of xylose and glucose in the hydrolysate was investigated under the conventional process conditions of hydrogen ion concentration from 0.05 to 0.2 mol/L and temperature from 150 to 200 ℃ . With a numerical calculation method, the kinetic parameters were estimated, and the activation energy of xylose and glucose in the degradation reaction was obtained. The kinetic equations correlating the effect of hydrogen ion concentration on the rate constants of degradation reaction were established. Comparison between the calculated results from the equations and experimental ones proved that the established kinetic model could satisfactorily predict the degradation behavior of xylose and glucose in the acidic hydrolysate.

Enhancement of Simultaneous Xylose and Glucose Utilization by Regulating ZWF1 and PGI1 in Saccharomyces Cerevisiae

Xylose utilization is one of the key issues in lignocellulose bioconversion. Because of glucose repression, in most engineered yeast with heterogeneous xylose metabolic pathway, xylose is not consumed until glucose is completely utilized. Although simultaneous glucose and xylose utilization have been achieved in yeast by RPE1 deletion, we regulated ZWF1 and PGI1 transcription to improve simultaneous xylose and glucose utilization by controlling the metabolic flux from glucose into the PP pathway. Xylose and glucose consumption increased by approximately 80 and 72%, respectively, whereas ZWF1 was overexpressed by multi-copy plasmids with a strong transcriptional promoter. PGI1 expression was knocked down by promoter replacement; the glucose and xylose metabolism increased when PGI1p was replaced by weak promoters, SSA1p and PDA1p. ZWF1 overexpression decreased while PGI1 down-regulation increased the ethanol yield to some extent in the recombinant strains. © 2017, The Author(s).

ETHANOL FERMENTATION OF MIXED GLUCOSE AND XYLOSE BY PICHIA STIPITIS

Pichia stipitis CBS 5773 yeast cells were used to ferment the mixed substrates consisted of glucose andxylose to produce ethanol.The effects of aeration rate,initial substrate concentration and pH on substrateutilization and ethanol yield were evaluated.During batch fermentation,the oscillation phenomena in cell growthwere observed at low aeration rate,whereas the diauxic growth at high aeration rate.The substrate utilizationratio and ethanol yield reached 95％ and 0.46g/g respectively under appropriate operation conditions.Amodified unstructural model was proposed to simulate the diauxic cell growth,substrate consumption andproduct formation.

New xylose transporters support the simultaneous consumption of glucose and xylose in Escherichia coli

Glucose and xylose are two major components of lignocellulose.Simultaneous consumption of glucose and xylose is critical for engineered microorganisms to produce fuels and chemicals from lignocellulosic biomass.Although many production limitations have been resolved,glucose‐induced inhibition of xylose transport remains a challenge.In this study,a cell growthbased screening strategy was designed to identify xylose transporters uninhibited by glucose.The glucose pathway was genetically blocked in Escherichia coli so that glucose functions only as an inhibitor and cells need xylose as the carbon source for survival.Through adaptive evolution,omics analysis and reverse metabolic engineering,a new phosphoenolpyruvate:carbohydrate phosphotransferase system(PTS)galactitol transporter(GalABC,encoded by EcolC_1640,EcolC_1641,and EcolC_1642 genes)that is not inhibited by glucose was identified.Inactivation of adenylate cyclase led to increased expression of the EcolC_1642 gene,and a point mutation in gene EcolC_1642(N13S)further enhanced xylose transport.During the second round of gene mining,AraE and a new ABC transporter(AraFGH)of xylose were identified.A point mutation in the transcription regulator araC(L156I)caused increased expression of araE and araFGH genes without arabinose induction,and a point mutation in araE(D223Y)further enhanced xylose transport.These newly identified xylose transporters can support the simultaneous consumption of glucose and xylose and have potential use in producing chemicals from lignocellulose.

Construction of a recombinant yeast strain converting xylose and glucose to ethanol

Candida shehatae gene xyl1 and Pichia stipitis gene xyl2,encoding xylose reductase(XR)and xylitol dehydrogenase(XD)respectively,were amplified by PCR.The genes xyl1 and xyl2 were placed under the control of promoter GAL in vector pYES2 to construct the recombinant expression vector pYES2-P12.Subsequently the vector pYES2-P12 was transformed into S.cerevisiae YS58 by LiAc to produce the recombinant yeast YS58-12.The alcoholic ferment indicated that the recombinant yeast YS58-12 could convert xylose to ethanol with the xylose consumption rate of 81.3%.

湿法糖基化改性大豆分离蛋白在低致敏千页豆腐中的应用

为寻求高效的糖基化改性条件和良好的应用途径,本文以葡萄糖、木糖两种单糖为糖基供体,探究反应时间、反应温度、蛋白与糖比例、蛋白浓度对大豆分离蛋白湿法糖基化反应的影响,分析大豆分离蛋白-葡萄糖复合物(SPI-葡萄糖)、大豆分离蛋白-木糖复合物(SPI-木糖)致敏性的变化,并将SPI-葡萄糖、SPI-木糖应用于低致敏千页豆腐生产。结果表明,木糖相较于葡萄糖更易与大豆分离蛋白发生糖基化反应,但也更容易有类黑素产生。在蛋白浓度为25 mg/mL时,糖基化反应程度最高,并且糖基化反应程度与反应温度、反应时间、糖添加量呈正相关。SDS-PAGE和傅里叶变换红外光谱分析结果表明糖基化改性使大豆分离蛋白和糖分子发生了共价结合,SPI的自由氨基减少。糖基化反应程度越高,SPI致敏性越低,SPI-木糖接枝物致敏性降低程度最高可达50%,以其为原料经谷氨酰胺转氨酶(TG酶)交联所制作的千页豆腐有良好的弹性和咀嚼性。

偏最小二乘辅助紫外可见光谱法同时测定烟草中的葡萄糖与木糖含量

烟草中含有葡萄糖、果糖、麦芽糖、蔗糖、木糖等多种糖类物质,占据烟草干重的25%~50%,是烟草的重要组成部分,也是评估烟草内在品质的重要指标。不同的糖类物质在卷烟燃烧过程中会生成不同产物,从而直接或间接地影响卷烟的香气和口感。建立烟草中各种单糖的测定方法,对烟草制品的质量控制具有现实意义。传统的检测方法如费林试剂法、连续流动分析法只能对烟草中的水溶性糖或总糖含量进行测定,无法对单一糖组分进行定量检测;气相色谱、液相色谱等方法虽能检测出不同单项,但是存在样品前处理过程麻烦、检测耗时较长等局限性。该工作在传统间苯三酚显色法测定木糖的基础上,以显色机理对该方法进行改进,解决了该检测体系下葡萄糖显色效果不佳的技术问题,可通过紫外可见光谱技术简单、高效地实现对烟草及卷烟制品中葡萄糖和木糖含量的精准测定。当同时测定上述两种糖组分时,由于二者的紫外可见光谱出峰位置相近,会相互影响彼此的测量准确性。为消除这一干扰,采用偏最小二乘回归法(PLS)建立光谱分析的多元校正模型,辅助改进后的间苯三酚法对烟草及其制品中葡萄糖和木糖含量进行同时检测。研究结果表明:改进后的间苯三酚法对于葡萄糖和木糖的单糖溶液,浓度分别在0.05~0.4和0.10~0.80 mmol·L^(-1)范围内时线性关系良好,该方法的检出限和定量限分别为0.001 7、 0.005 7 mmol·L^(-1)和0.007 2、 0.024 mmol·L^(-1),批内变异系数的范围为0.69%~3.03%,加标回收率范围为96.72%~102.85%,提取液中木素含量对测定结果没有显著干扰。对于葡萄糖和木糖组成的混糖溶液,采用外部检验对模型效果进行评价,外部检验集的预测值与理论值的相关系数R^(2)=0.994 7,相对偏差小于10%。该方法能够快速准确的测定烟草及烟草制品中葡萄糖和木糖含量,为烟草行业提供一种有效的单糖分析方法。

木糖对淀粉体外消化性的影响及作用机理

淀粉是日常饮食中的主要碳水化合物来源,淀粉消化的快慢是影响机体餐后血糖水平的重要因素。本文以木糖为研究对象,探究了木糖对玉米淀粉体外消化特性的影响及其作用机理。通过体外模拟消化实验测定了不同添加量的木糖(5%、10%、15%)对淀粉体外消化性的影响,利用酶抑制动力学、分子对接、人体血糖生成指数(GI)测试研究了木糖对α-葡萄糖苷酶和α-淀粉酶的作用机理及其对血糖波动的影响。结果表明,不同添加量的木糖均能抑制玉米淀粉的消化,木糖对α-葡萄糖苷酶和α-淀粉酶的半数抑制浓度(IC50值)分别为205.35和4.75 mg/mL,抑制类型属于混合型抑制。木糖通过氢键与α-葡萄糖苷酶和α-淀粉酶的氨基酸残基相互作用,其结合能分别为-3.05和-5.30 kcal/mol。添加木糖后,植物基肽素乳的GI值由58下降至45,表明木糖能够降低餐后血糖波动。该结果可为木糖在营养健康食品中的研究和应用提供科学的数据支持。

DNS法测定还原糖含量时最适波长的确定

探讨DNS法测定还原糖含量时的最适波长。以DNS为显色剂，用分光光度法分析测定了木糖和葡萄糖显色液的最大吸收波长和最适测定波长。结果表明，木糖和葡萄糖与DNS显色剂反应后，均在490nm处有最大吸收峰。标准曲线糖含量范围为0～40mg／L时，OD值在520nm处的群最接近于1，精确度和回收率均较高。提示DNS法测定还原糖含量时，520nm为最适测定波长。

大黄素对小肠运动的影响及其机制

目的 研究大黄素 (emodin)对便秘小鼠小肠运动的影响 ,并探讨其作用机制。方法 通过小肠炭末推进实验和木糖吸收实验 ,观察大黄素对便秘小鼠小肠运动的影响 ;通过小鼠离体翻转小肠囊的方法 ,观察大黄素对小肠葡萄糖 -钠转运电位 (PD)的影响 ,借以了解其对与PD关系密切的Na+ ,K+ ATP酶的影响。结果 大黄素 0 1和 0 2 g·kg- 1灌胃给药可以明显增强小鼠小肠炭末推进运动 ,影响小肠对木糖的吸收 ;高糖K H液配制的大黄素 0 2、0 4、0 8和 1 6g·L- 1均可明显降低小鼠离体小肠PD ,而无糖K H液配制的大黄素则无此作用。结论 大黄素可促进小肠蠕动 ,这一作用与其抑制Na+ ,K+

少根根霉利用木糖和葡萄糖分步发酵制备富马酸

将木糖与葡萄糖分别用于少根根霉种子培养及发酵产富马酸2个阶段,少根根霉利用木糖进行种子培养时,最适木糖浓度为30g/L,摇瓶最适孢子浓度为(4～6)×105mL-1,最佳种龄32～40h,最适接种量为8%(φ),在含有100g/L葡萄糖的产酸发酵培养基中发酵72h后,富马酸最高浓度达53.51g/L.研究结果表明,可以利用木糖替代葡萄糖进行少根根霉的种子培养,分步发酵制备富马酸.

木质纤维素酒精发酵菌种的筛选

为对木质纤维素水解糖液进行酒精发酵 ,同时代谢葡萄糖和木糖成酒精的 9个菌种以木糖为唯一碳源进行驯化 ,从中选出 3个菌株。并对 3个菌株进行固定化 ,进行酒精发酵研究 ,以进一步阐明该菌株代谢葡萄糖和木糖成酒精的能力。以总糖利用率、葡萄糖和木糖利用率、酒精产率为指标 ,3株菌具有较好的同时发酵葡萄糖和木糖成酒精的能力。PachysolentannophilisATCC 32 72 8的总糖 (5 %葡萄糖和 2 %木糖 )利用率达到了 85 .0 8% (36h) ,葡萄糖的利用率为99.2 1% (36h) ,木糖利用率 80 .38% (36h) ,菌株CadidashehataeATCC 34887的酒精产率达到理论值的 82 .91%。

戊糖和己糖共发酵生产燃料乙醇条件研究

利用嗜鞣管囊酵母P-01对木糖和葡萄糖共发酵生产燃料乙醇的条件进行了试验研究,结果表明,木糖和葡萄糖混合液生产燃料乙醇的最佳条件为发酵液的pH值5.5、30℃、摇床转速120 r/min、接种量10%、发酵液初始糖浓度6%、葡萄糖与木糖之比为2、发酵周期为84h。在最佳发酵条件下,发酵醪液中的燃料乙醇浓度为2.101%,糖醇转化率为35%。

提高木糖和葡萄糖乙醇产率的菌种驯化

为提高酵母菌代谢木糖和葡萄糖产乙醇的效率,以木糖为底物对利用木糖和葡萄糖的3株酵母菌进行驯化培养,通过对糖的利用率和乙醇产率的分析表明,经7个批次的驯化,3个菌株的木糖利用率和乙醇产率都得到了明显提高。驯化后的3个菌株经固定化细胞乙醇发酵,结果表明,ATCC 32728(P.tannoph ilis)的木糖利用率为87.90%(36h),葡萄糖利用率为99.99%(24h),混合糖(70g/L,木糖∶葡萄糖=2∶5,24h)利用率为93.95%,乙醇产率达到了99.99%。Pachysolen tannoph ilis ATCC 32728经驯化,并用固定化细胞进行乙醇发酵,使混合糖的利用率和乙醇产率达到了理想的效果。

离子排斥色谱法同时测定2,3-丁二醇发酵液中的葡萄糖和木糖及各种代谢产物

针对2,3-丁二醇发酵体系,以高交联度磺化苯乙烯-二乙烯基苯共聚物多孔微球为固定相的AminexHPX-87H离子色谱柱为分析柱,利用示差折光检测器对该体系中的6种代谢产物(2,3-丁二醇、3-羟基丁酮、乙醇、乙酸、甲酸和乳酸)以及2种残留底物葡萄糖和木糖进行了分离。在65℃柱温下,以5 mmol/L H2SO4作为流动相,发酵液样品中底物葡萄糖和木糖及2,3-丁二醇等各种代谢产物的线性相关系数均在0.9990～0.9999之间,回收率为98.8%～103.2%,精密度为0.3%～2.1%。在最佳色谱条件下,能够同时测定2,3-丁二醇发酵体系中的残留底物和各种代谢产物的含量,适合于实时定量监测2,3-丁二醇发酵过程。

葡萄糖和木糖双底物生物合成2,3-丁二醇的条件优化

针对利用葡萄糖和木糖合成2,3-丁二醇的Klebsiella pneumoniaeXJ-Li菌,优化培养基组成与发酵条件,围绕五、六碳糖共代谢的特点,探讨简单可行的代谢调控方法.结果表明,60g/L葡萄糖和40g/L木糖为碳源,5.75g/L NH4H2PO4为氮源,pH值维持在5.5,培养温度38℃,2,3-丁二醇浓度可达19.24g/L.确定了pH值调控和外源添加维生素C的调控方式,通过调节发酵过程中pH值于5.5左右,使2,3-丁二醇的产量提高了16.4%;添加60mg/L维生素C调节培养基的氧化还原状态,可使2,3-丁二醇的产量提高44.3%,批式发酵48h,2,3-丁二醇终浓度可达33.47g/L.

蔗渣水解液发酵乙醇的研究

研究了酵母（Ｐｉｃｈｉａｓｔｉｐｉｔｉｓ）Ｙ７１２４在限制供氧条件下尽管反应初期葡萄糖消耗速率大于木糖，但在一定时间后，葡萄糖的消耗速率变慢，而木糖消耗速率变快直至耗尽的现象。建立了气升柱以Ｐ．ｓｔｉｐｉｔｉｓ转化木糖为目的和以溢流柱Ｓａｃｈａｒｏｍｙｃｅｓｃｅｒｉｖｉｓｉａｅ转化残留葡萄糖为目的的串联发酵乙醇工艺，即流加５倍浓缩的蔗渣水解液，Ｄ＝０１ｈ－１，还原糖总利用率为９７２％，酒精浓度为４６５ｇ／Ｌ，生产率为４１ｇ／Ｌ·ｈ。

嗜热脂肪芽孢杆菌耐热木糖异构酶的特性

嗜热脂肪芽抱杆菌在木糖或木聚糖诱导下产生木糖异构酶。从破碎细胞中分离到该酶。经硫酸铵沉淀，热处理及SephadexG-200柱层析等步骤获得纯化了19倍的酶制备物。该酶反应的最适pH值为7.5，在pH6．2～8．0范围内稳定，最适反应温度为80℃，低于此温度时酶有很好稳定性。该酶对底物木糖的Km值为6．67mmol／L，Mg2+、Co2+和Mn2+对该酶有激活作用，而Zn2+、Cu2+和Fe2+对酶有抑制作用。酶制备物转化木糖为木酮糖产率为18％。

葡萄糖和木糖共发酵生产L-乳酸的培养基和培养条件响应面优化

为提高米根霉利用葡萄糖、木糖共发酵产L-乳酸的产量,在单因素试验基础上,采用响应面法进行培养基和培养条件优化的试验方案设计。利用Design Expert软件对其结果进行二次回归分析,获得的最佳产酸条件为:葡萄糖100g/L、木糖50g/L、(NH4)2SO4 3.0g/L、KH2PO4 0.3g/L、摇床转速180r/min、温度32℃、接种量12%、装液量50mL。该条件下摇瓶发酵72h,L-乳酸产量为119.216g/L,转化率为79.48%。

Candida shehatae的纯化及其利用木糖和葡萄糖发酵的特性研究

通过对休哈塔假丝酵母TZ1分离纯化以获取高产乙醇菌株,并对木糖、葡萄糖以及不同比例的混合糖发酵产乙醇进行实验研究。结果显示,筛选出的TZ8-13对木糖和葡萄糖都有良好的发酵性能,糖浓度为60g/L时的乙醇产量分别达到了21.6g/L和24.2g/L,糖利用率分别为97.81%(72h)和99.13%(36h),较初始菌株TZ1发酵木糖乙醇产量提高了55.38%、木糖利用率提高了19.54%;混合糖发酵存在糖的二次利用关系,TZ8-13首先利用葡萄糖。木糖和葡萄糖比为1:1时乙醇产量为22.8g/L。