黄原胶寡糖生物活性的研究

利用黄原胶降解菌Cellulom onassp.XT11生产的黄原胶降解酶,对黄原胶进行生物降解,生产具有不同粘度/还原末端比的黄原胶寡糖,并研究了黄原胶寡糖在清除羟基自由基、植物防卫反应中激活因子活性和对植物病原菌抑制能力等方面的生物活性,结果表明黄原胶寡糖具有清除羟基自由基能力,并能激活植物防卫系统以抵御病原菌的侵染,同时对野油菜黄单孢菌也具有抑菌活性。     

改性黄原胶酯化条件的优化及结构的表征

为了提高黄原胶的速溶性和粘度,将黄原胶进行改性处理。将黄原胶与马来酸酐进行酯化反应,探讨了黄原胶与马来酸酐摩尔比、反应时间和反应温度等因素的影响,以取代度为指标,利用响应面方法确定,该酯化反应的最优条件为:黄原胶与马来酸酐摩尔比1∶11.5、反应时间24.4 h、反应温度66℃。对改性黄原胶进行红外光谱、光散射和X-射线衍射等结构表征,表明酯化改性成功,且进一步解释了速溶性和粘度提高的原因。改性黄原胶细胞毒性实验,显示无毒性。结果表明,改性黄原胶的速溶性和粘度有很大提高,0.2%改性黄原胶的速溶性和粘度较对照提高了近3倍,在食品、药品等领域具有潜在的应用价值。     

黄原胶降解菌BIT-BJ001培养条件的优化

黄原胶在采油工程中有重要的应用,但其难降解性质给采油工程带来很多问题。从塔里木油田胡杨木根部样品中分离得到1株黄原胶降解菌BIT-BJ001,对其发酵条件的研究表明,此黄原胶降解菌最适培养条件为:黄原胶0.3%,酵母粉0.5%,Na+浓度0.8%,Mg2+浓度0.8%,初始pH值为10,温度60℃。菌种BIT-BJ001降解黄原胶的能力与发酵时间、发酵液中还原糖浓度有关,发酵96 h,黄原胶降粘率达到最高,发酵液中还原糖浓度过高,将抑制菌株对黄原胶的降解。     

新分离Microbacterium sp．XT11菌产黄原胶降解酶生产条件的优化研究

新分离Microbacterium sp．XT11菌能够合成黄原胶降解酶,将植物病原菌野油菜黄单孢菌分泌的毒素因子黄原胶分解,生成具有激发子和抗微生物活性的黄原胶寡糖。实验确认,黄原胶和酵母浸粉分别是XT11菌生产黄原胶降解酶的最适碳源和氮源,获得最高酶活力的最低碳源和氮源浓度均为0.3％。XT11菌生产黄原胶降解酶的最适条件为：培养温度28℃,培养基起始pH7.0,转速150r／min。     

新分离Microbacterium sp. XT11菌产黄原胶降解酶生产条件的优化研究

新分离Microbacteriumsp.XT11菌能够合成黄原胶降解酶,将植物病原菌野油菜黄单孢菌分泌的毒素因子黄原胶分解,生成具有激发子和抗微生物活性的黄原胶寡糖。实验确认,黄原胶和酵母浸粉分别是XT11菌生产黄原胶降解酶的最适碳源和氮源,获得最高酶活力的最低碳源和氮源浓度均为0.3%。XT11菌生产黄原胶降解酶的最适条件为:培养温度28℃,培养基起始pH7.0,转速150r/min。     

黄原胶的水解酶及其应用

黄原胶易被芽孢杆菌产生的黄原胶酶(Xanthanase)和真菌产生的纤维素酶(在提高温度和无离子的条件下)所降解,使之转化为低分子量的单糖和不同大小片段的低聚糖。利用这些酶系可对黄原胶和与其相关的多糖进行结构分析,并能提供对黄原胶有用的特异性测定方法。     

野油菜黄单胞菌低温分泌黄原胶微细结构特征和化学特性

首次发现２８℃培养至对数期且未分泌黄原胶的野油菜黄单胞菌（Ｘａｎｔｈｏｍｏｎａｓ ｃａｍｐｅｓｔｒｉｓ）移 至４℃低温培养仍合成分泌黄原胶。黄原胶低温分泌最微细的结构单位是微丝,多根微丝进一步组成 纤维、类似双螺旋或纤维束等级结构形式。低温分泌的黄原胶与２８℃常温分泌的黄原胶相比有相同 的化学组成与结构,但分子量、丙酮酸含量低。     

黄原胶降解的研究进展

综述了黄原胶的理化特性、降解意义及降解方法,重点介绍了生物法降解黄原胶的国内外研究进展,并对降解黄原胶的研究方向提出了寻求更多降解途径、开发寡糖产品等建议.     

黄原胶寡糖的抗氧化性能和非酶糖基化抑制作用研究

分别在酸性和碱性条件下通过氧化降解制备了两种黄原胶寡糖XG-H和XG-OH.红外光谱法对黄原胶寡糖的结构进行表征,凝胶渗透色谱法测定黄原胶寡糖的分子量,紫外可见分光光度法测定黄原胶寡糖的丙酮酸和还原糖含量,考察了两种黄原胶寡糖的抗氧化性能和非酶糖基化(NEG)的抑制作用.结果表明,XG-H和XG-OH都表现出一定的抗氧化能力且XG-OH强于XG-H; XG-OH促进5-羟甲基糠醛(非酶糖基化中间产物)的生成,但可显著抑制非酶糖基化荧光末端产物的生成.而XG-H表现出非酶糖基化促进作用.这可能与两种黄原胶寡糖的丙酮酸和还原糖含量有关.     

黄原胶中丙酮酸含量的研究

本文比较了野油菜黄单胞菌(Xanthomonas campestris)不同菌株及不同菌落在同一条件下以及N·K—01菌株在不同条件下所产黄原胶的丙酮酸含量;检查了不同丙酮酸含量黄原胶的流变学性质.研究表明,选择适当菌株,控制发酵条件,可以得到不同丙酮酸含量的黄原胶;胶中丙酮酸含量越高,其流变学性质越好.丙酮酸含量是黄原胶质量的重要指标。     

Studies on xanthan production from Xanthomonas campestris

Xanthan is an heteropolysaccharide produced by Xanthomonascampestris. Xanthan gum fermentation by a local isolate of X. campestris using different carbon sources was studied. The production of polysaccharide was influenced by the carbon source used. The production of the xanthan was 15.654 g/l with synthetic medium. Production of xanthan at various temperatures ranging between 25v°C and 40v°C was studied. The growth and production was maximum between 25-30v°C. Xanthan production was maximum at pH 7.0-7.5.     

Agitator speed and dissolved oxygen effects in xanthan fermentations

Agitation speed affects both the extent of motion in Xanthan fermentation broths because of their rheological complexity and the rate of oxygen transfer. The combination of these two effects causes the dissolved oxygen concentration and its spatial uniformity also to change with agitator speed. Separating these complex interactions has been achieved in this study in the following way. First, the influence of agitation speeds of 500 and 1000 rpm has been investigated at a constant nonlimiting dissolved oxygen concentration of 20% of air saturation using gas blending. Under these controlled dissolved oxygen conditions, the results demonstrate that the biological performance of the culture was independent of agitation speed as long as broth homogeneity could be ensured. With the development of increasing rheological complexity lending to stagnant regions at Xanthan concentrations >20 g/L, it is shown that the superior bulk mixing achieved at 1000 rpm, compared with 500 rpm, leading to an increased proportion of the cells in the fermentor to be metabolically active and hence higher microbial oxygen uptake rates, was responsible for the enhanced performance. Second, the effects of varying dissolved oxygen are compared with a control in each case with an agitator speed of 1000 rpm to ensure full motion, but with a fixed, nonlimiting dissolved oxygen of 20% air saturation. The specific oxygen uptake rate of the culture in the exponential phase, determined using steady-state gas analysis data, was found to be independent of dissolved oxygen above 6% air saturation, whereas the specific growth rate of the culture was not influenced by dissolved oxygen, even at levels as low as 3%, although a decrease in Xanthan production rate could be measured. In the production phase, the critical oxygen level was determined to be 6% to 10%, so that, below this value, both specific Xanthan production rate as well as specific oxygen uptake rate decreased significantly. In addition, it is shown that the dynamic method of oxygen uptake determination is unsuitable even for moderately viscous Xanthan broths. Copyright 1998 John Wiley & Sons, Inc.     

Flocculation properties of xanthan produced by Xanthomonas campestris

Summary Xanthan had a flocculating activity in a kaolin suspension and high flocculating activity was obtained in the suspension (pH 7.0) adding Al³⁺, Fe³⁺ or Fe²⁺. Xanthan had high flocculating activity not only in other inorganic suspensions such as active carbon and acid clay but also in organic suspensions of cellulose and yeast. From these flocculation properties, xanthan is anticipated to be utilized in wide areas as a new biodegradable, harmless biopolymer flocculant.     

The influence of impeller type in pilot scale xanthan fermentations

The rheological complexity of Xanthan fermentations presents an interesting problem from a mixing viewpoint, because the phenomena of poor bulk blending and low oxygen mass transfer rates inherent in highly viscous fermentations (and their consequences) can be systematically investigated, even at the pilot plant scale. This study in a 150 L fermentor compares the physical and biological performance of four pairs of impellers: a standard Rushton turbine, a large diameter Rushton turbine, a Prochem Maxflo T, and a Scaba 6SRGT. Accurate in-fermentor power measurements, essential for the comparison of impellers in relation to operating costs are also reported. It is demonstrated that the agitator performance in Xanthan fermentations is very specific and the choice of which impeller to use in bioreactors to obtain enhanced performance is dependant on the applied criterion. None of the criterion favored the use of the standard Rushton turbine, therefore suggesting that there are strong grounds for retrofitting these impellers with either large diameter impellers of similar design or with novel agitators. In addition, fluid dynamic modeling of cavern formation has clearly highlighted the importance of a well mixed and oxygenated region for providing the capacity for high microbial oxygen uptake rates which govern Xanthan productivity and quality. Copyright 1998 John Wiley & Sons, Inc.     

野油菜黄单胞菌原质体分泌黄原胶的电镜观察

经透射电镜观察首次发现野油菜黄单胞菌（Xanthomonas campestris）原生质体在以蔗糖为底物的高渗营养液中,能合成并分泌丝状黄原胶。     

Xanthan gum: an economical substitute for agar in plant tissue culture media

Xanthan gum, a microbial desiccation-resistant polysaccharide prepared commercially by aerobic submerged fermentation from Xanthomonas campestris, has been successfully used as a solidifying agent for plant tissue culture media. Its suitability as a substitute to agar was demonstrated for in vitro seed germination, caulogenesis and rhizogenesis of Albizzia lebbeck, androgenesis in anther cultures of Datura innoxia, and somatic embryogenesis in callus cultures of Calliandra tweedii. Culture media used for eliciting these morphogenic responses were gelled with either 1% xanthan gum or 0.9% agar. Xanthan gum, like agar, supported all these responses.     

Chemical modification of xanthan gum to increase dissolution rate

Xanthan gum is modified with formaldehyde to improve the dissolution rate. The FT-IR spectra and the X-ray diffraction spectra both show that chemical modification reduces intermolecular interactions and crystallinity. Viscosity measurements show that the chemically modified gum dissolves more rapidly than before.     

Rheological properties of extracellular polysaccharide, Pestan, produced by Pestalotiopsis sp.

Summary The fluid behaviour of Pestan produced from Pestalotiopsis sp. KCTC 8637P was as a non-Newtonian fluid. The rheological behaviour of Pestan solution was examined by Power-law model, Herschel-Bulkley model and Arrhenius equation. As the result, Pestan solution was pseudoplastic behaviour with yield stress. According to increase of Pestan concentration, its flow index was decreased. Thus, low concentrations of Pestan solution were well exposed pseudoplastic property. Apparent viscosity of 0.2 % Pestan solution was 268.2 cP at 14.3 sec^–1 and was higher about 2.8 times than that of Xanthan gum solution. Apparent viscosity of Pestan solution was stable over a wide pH and was maximum at pH 8. Also, consistency index of Pestan solution was very stable over wide temperature than that of Xanthan gum solution.     

Xanthan gum: production, recovery, and properties

Xanthan gum is a microbial polysaccharide of great commercial significance. This review focuses on various aspects of xanthan production, including the producing organism Xanthomonas campestris, the kinetics of growth and production, the downstream recovery of the polysaccharide, and the solution properties of xanthan.     

黄原胶(Xanthan Gum)的特性、生产及应用

黄原胶是野油菜黄单孢菌分泌于胞外的中性水溶性多糖。由于其独特的流变性质而有着极其广泛的工业应用。介绍了黄原胶的生产、特性、降解以及应用,并对其应用潜力作了预测。